Your search keyword '"Y.X. Yang"' showing total 122 results

51. Changes in expression of antimicrobial peptides and Fc receptors in the small intestines of neonatal calves during the passive immunity period

Author

Y.X. Qi, H.L. Zhao, Y.X. Yang, G.L. Cheng, D.W. Huang, H.L. Zhu, X.Z. Wang, and X.W. Zhao

Subjects

Pore Forming Cytotoxic Proteins, medicine.medical_treatment, Fc receptor, Gene Expression, Ileum, Passive immunity, Receptors, Fc, digestive system, Jejunum, Andrology, 03 medical and health sciences, Intestine, Small, Genetics, medicine, Animals, Receptor, 030304 developmental biology, 0303 health sciences, biology, Chemistry, digestive, oral, and skin physiology, 0402 animal and dairy science, 04 agricultural and veterinary sciences, 040201 dairy & animal science, Small intestine, medicine.anatomical_structure, Animals, Newborn, biology.protein, Duodenum, Colostrum, Animal Science and Zoology, Cattle, Immunity, Maternally-Acquired, Food Science

Abstract

The contribution of colostrum to passive immunity transfer and intestinal protection is well known; however, the effects of colostrum intake on the expression of antimicrobial peptides (AP) and Fc receptors in the intestine of neonatal calves are unclear. Our aim was to investigate changes in the expression of AP and Fc receptor in the small intestine of calves in the first 36 h postpartum. Twenty-four Holstein bull calves were used in this study, of which 18 calves were administered 3.2 L of pooled colostrum for each calf per meal via an esophageal tube. Calves were slaughtered at 8 h (1 meal at 1-2 h), 24 h (2 meals at 1-2 h and 10-12 h), and 36 h (3 meals at 1-2 h, 10-12 h, and 22-24 h) postpartum. The remaining 6 calves without any milk administration were slaughtered at 2 h postpartum. Samples of blood and jejunum digesta were collected to determine immunoglobulin concentration using ELISA. Samples of the duodenum, jejunum, and ileum tissues after slaughter were collected to determine AP and Fc receptor expression using quantitative real-time PCR. In calves administered colostrum, IgG concentration in jejunum digesta rapidly decreased in an age-dependent manner (33.41, 9.47, and 0.34 mg/mL at 8, 24, and 36 h, respectively), whereas serum IgG concentration increased significantly, from 0.25 μg/mL at 2 h to 21.72 mg/mL at 24 h. Cathelicidin-4, β-defensin (DEFB)-7, and enteric β-defensin expression was upregulated at 8 h postpartum in the duodenum and jejunum compared with that at 2 h, but progressive recovery was detected from 24 h onward. Higher expression of cathelicidin-4, regenerating family member 3γ, lysozyme (LYZ), LYZ1, and LYZ2 and lower expression of DEFB, DEFB1, DEFB7, DEFB10, and enteric β-defensin were observed in the duodenum and jejunum compared with the ileum. Differences in AP expression between intestinal regions suggested that the innate immune defense mechanism varied significantly among the duodenum, jejunum, and ileum. No difference in the expression of Fc fragment of the IgG receptor was observed either among ages or small intestinal regions. The Fcγ receptor (FcγR)Ia and FcγRIIb expression was the highest at 8 h compared with that at 2, 24, and 36 h, and expression of FcγRIa, FcγRIIb, and FcγRIIIa was higher in the duodenum and jejunum than in the ileum. These results indicated that AP and Fcγ receptors might play important roles in intestinal defense during the passive immunity period.

Published

2019

52. Observation of ψ(3686)→η′e+e−

Author

M. Ablikim, M.N. Achasov, S. Ahmed, M. Albrecht, M. Alekseev, A. Amoroso, F.F. An, Q. An, J.Z. Bai, Y. Bai, O. Bakina, R. Baldini Ferroli, Y. Ban, K. Begzsuren, D.W. Bennett, J.V. Bennett, N. Berger, M. Bertani, D. Bettoni, F. Bianchi, E. Boger, I. Boyko, R.A. Briere, H. Cai, X. Cai, O. Cakir, A. Calcaterra, G.F. Cao, S.A. Cetin, J. Chai, J.F. Chang, G. Chelkov, G. Chen, H.S. Chen, J.C. Chen, M.L. Chen, P.L. Chen, S.J. Chen, X.R. Chen, Y.B. Chen, W. Cheng, X.K. Chu, G. Cibinetto, F. Cossio, H.L. Dai, J.P. Dai, A. Dbeyssi, D. Dedovich, Z.Y. Deng, A. Denig, I. Denysenko, M. Destefanis, F. De Mori, Y. Ding, C. Dong, J. Dong, L.Y. Dong, M.Y. Dong, Z.L. Dou, S.X. Du, P.F. Duan, J. Fang, S.S. Fang, Y. Fang, R. Farinelli, L. Fava, S. Fegan, F. Feldbauer, G. Felici, C.Q. Feng, E. Fioravanti, M. Fritsch, C.D. Fu, Q. Gao, X.L. Gao, Y. Gao, Y.G. Gao, Z. Gao, B. Garillon, I. Garzia, A. Gilman, K. Goetzen, L. Gong, W.X. Gong, W. Gradl, M. Greco, M.H. Gu, Y.T. Gu, A.Q. Guo, R.P. Guo, Y.P. Guo, A. Guskov, Z. Haddadi, S. Han, X.Q. Hao, F.A. Harris, K.L. He, X.Q. He, F.H. Heinsius, T. Held, Y.K. Heng, T. Holtmann, Z.L. Hou, H.M. Hu, J.F. Hu, T. Hu, Y. Hu, G.S. Huang, J.S. Huang, X.T. Huang, X.Z. Huang, Z.L. Huang, T. Hussain, W. Ikegami Andersson, M. Irshad, Q. Ji, Q.P. Ji, X.B. Ji, X.L. Ji, X.S. Jiang, X.Y. Jiang, J.B. Jiao, Z. Jiao, D.P. Jin, S. Jin, Y. Jin, T. Johansson, A. Julin, N. Kalantar-Nayestanaki, X.S. Kang, M. Kavatsyuk, B.C. Ke, T. Khan, A. Khoukaz, P. Kiese, R. Kiuchi, R. Kliemt, L. Koch, O.B. Kolcu, B. Kopf, M. Kornicer, M. Kuemmel, M. Kuessner, A. Kupsc, M. Kurth, W. Kühn, J.S. Lange, M. Lara, P. Larin, L. Lavezzi, H. Leithoff, C. Li, Cheng Li, D.M. Li, F. Li, F.Y. Li, G. Li, H.B. Li, H.J. Li, J.C. Li, J.W. Li, Jin Li, K.J. Li, Kang Li, Ke Li, Lei Li, P.L. Li, P.R. Li, Q.Y. Li, W.D. Li, W.G. Li, X.L. Li, X.N. Li, X.Q. Li, Z.B. Li, H. Liang, Y.F. Liang, Y.T. Liang, G.R. Liao, L.Z. Liao, J. Libby, C.X. Lin, D.X. Lin, B. Liu, B.J. Liu, C.X. Liu, D. Liu, D.Y. Liu, F.H. Liu, Fang Liu, Feng Liu, H.B. Liu, H.L. Liu, H.M. Liu, Huanhuan Liu, Huihui Liu, J.B. Liu, J.Y. Liu, K. Liu, K.Y. Liu, Ke Liu, L.D. Liu, Q. Liu, S.B. Liu, X. Liu, Y.B. Liu, Z.A. Liu, Zhiqing Liu, Y.F. Long, X.C. Lou, H.J. Lu, J.G. Lu, Y. Lu, Y.P. Lu, C.L. Luo, M.X. Luo, X.L. Luo, S. Lusso, X.R. Lyu, F.C. Ma, H.L. Ma, L.L. Ma, M.M. Ma, Q.M. Ma, T. Ma, X.N. Ma, X.Y. Ma, Y.M. Ma, F.E. Maas, M. Maggiora, Q.A. Malik, A. Mangoni, Y.J. Mao, Z.P. Mao, S. Marcello, Z.X. Meng, J.G. Messchendorp, G. Mezzadri, J. Min, R.E. Mitchell, X.H. Mo, Y.J. Mo, C. Morales Morales, N.Yu. Muchnoi, H. Muramatsu, A. Mustafa, Y. Nefedov, F. Nerling, I.B. Nikolaev, Z. Ning, S. Nisar, S.L. Niu, X.Y. Niu, S.L. Olsen, Q. Ouyang, S. Pacetti, Y. Pan, M. Papenbrock, P. Patteri, M. Pelizaeus, J. Pellegrino, H.P. Peng, Z.Y. Peng, K. Peters, J. Pettersson, J.L. Ping, R.G. Ping, A. Pitka, R. Poling, V. Prasad, H.R. Qi, M. Qi, T. .Y. Qi, S. Qian, C.F. Qiao, N. Qin, X.S. Qin, Z.H. Qin, J.F. Qiu, K.H. Rashid, C.F. Redmer, M. Richter, M. Ripka, A. Rivetti, M. Rolo, G. Rong, Ch. Rosner, A. Sarantsev, M. Savrié, C. Schnier, K. Schoenning, W. Shan, X.Y. Shan, M. Shao, C.P. Shen, P.X. Shen, X.Y. Shen, H.Y. Sheng, X. Shi, J.J. Song, W.M. Song, X.Y. Song, S. Sosio, C. Sowa, S. Spataro, G.X. Sun, J.F. Sun, L. Sun, S.S. Sun, X.H. Sun, Y.J. Sun, Y.K. Sun, Y.Z. Sun, Z.J. Sun, Z.T. Sun, Y.T. Tan, C.J. Tang, G.Y. Tang, X. Tang, I. Tapan, M. Tiemens, B. Tsednee, I. Uman, G.S. Varner, B. Wang, B.L. Wang, D. Wang, D.Y. Wang, Dan Wang, K. Wang, L.L. Wang, L.S. Wang, M. Wang, Meng Wang, P. Wang, P.L. Wang, W.P. Wang, X.F. Wang, Y. Wang, Y.F. Wang, Y.Q. Wang, Z. Wang, Z.G. Wang, Z.Y. Wang, Zongyuan Wang, T. Weber, D.H. Wei, P. Weidenkaff, S.P. Wen, U. Wiedner, M. Wolke, L.H. Wu, L.J. Wu, Z. Wu, L. Xia, Y. Xia, D. Xiao, Y.J. Xiao, Z.J. Xiao, Y.G. Xie, Y.H. Xie, X.A. Xiong, Q.L. Xiu, G.F. Xu, J.J. Xu, L. Xu, Q.J. Xu, Q.N. Xu, X.P. Xu, F. Yan, L. Yan, W.B. Yan, W.C. Yan, Y.H. Yan, H.J. Yang, H.X. Yang, L. Yang, Y.H. Yang, Y.X. Yang, Yifan Yang, Z.Q. Yang, M. Ye, M.H. Ye, J.H. Yin, Z.Y. You, B.X. Yu, C.X. Yu, J.S. Yu, C.Z. Yuan, Y. Yuan, A. Yuncu, A.A. Zafar, Y. Zeng, Z. Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.H. Zhang, H.Y. Zhang, J. Zhang, J.L. Zhang, J.Q. Zhang, J.W. Zhang, J.Y. Zhang, J.Z. Zhang, K. Zhang, L. Zhang, T.J. Zhang, X.Y. Zhang, Y. Zhang, Y.H. Zhang, Y.T. Zhang, Yang Zhang, Yao Zhang, Yu Zhang, Z.H. Zhang, Z.P. Zhang, Z.Y. Zhang, G. Zhao, J.W. Zhao, J.Y. Zhao, J.Z. Zhao, Lei Zhao, Ling Zhao, M.G. Zhao, Q. Zhao, S.J. Zhao, T.C. Zhao, Y.B. Zhao, Z.G. Zhao, A. Zhemchugov, B. Zheng, J.P. Zheng, Y.H. Zheng, B. Zhong, L. Zhou, Q. Zhou, X. Zhou, X.K. Zhou, X.R. Zhou, X.Y. Zhou, Xiaoyu Zhou, Xu Zhou, A.N. Zhu, J. Zhu, K. Zhu, K.J. Zhu, S. Zhu, S.H. Zhu, X.L. Zhu, Y.C. Zhu, Y.S. Zhu, Z.A. Zhu, J. Zhuang, B.S. Zou, and J.H. Zou

Subjects

Dalitz decay, Nuclear and High Energy Physics, Meson, Electron–positron annihilation, BESIII, Charmonium, e+e− Annihilation, e + e − Annihilation, 01 natural sciences, Omega, NO, law.invention, e+e−Annihilation, Nuclear physics, law, 0103 physical sciences, 010306 general physics, Collider, Physics, 010308 nuclear & particles physics, Generator (category theory), Branching fraction, Pseudoscalar

Abstract

Using a data sample of 448.1 × 10 6 ψ ( 3686 ) events collected with the BESIII detector at the BEPCII collider, we report the first observation of the electromagnetic Dalitz decay ψ ( 3686 ) → η ′ e + e − , with significances of 7.0σ and 6.3σ when reconstructing the η ′ meson via its decay modes η ′ → γ π + π − and η ′ → π + π − η ( η → γ γ ), respectively. The weighted average branching fraction is determined to be B ( ψ ( 3686 ) → η ′ e + e − ) = ( 1.90 ± 0.25 ± 0.11 ) × 10 − 6 , where the first uncertainty is statistical and the second systematic.

Published

2018

53. A comparison of the performance of submerged and detached artificial headlands in a beach nourishment project

Author

J.B. Zhang, Yao Zhang, S. Yin, Yongping Chen, Y.X. Yang, Y.B. Yang, Cuiping Kuang, R.F. Qiu, and Yi Pan

Subjects

0106 biological sciences, Shore, Hydrology, geography, Environmental Engineering, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 010604 marine biology & hydrobiology, Flushing time, Ocean Engineering, Water exchange, 01 natural sciences, Siltation, Headland, Environmental science, Beach nourishment, 0105 earth and related environmental sciences

Abstract

Submerged Artificial Headland (SAH) and Detached Artificial Headland (DAH) are two types of modified artificial headland to provide better water exchange at slightly weakening beach protection effect compared to Traditional Artificial Headland (TAH). In this paper a numerical investigation is conducted on performances of SAH and DAH in a beach nourishment project. The beach protection and water exchange are considered respectively. A shoreline model and a constituent transport model are set up to simulate the post-project shoreline change and water exchange. The results of shoreline changed model show that both the SAH and DAH have good performance in protecting the beach behind them, while in SAH case the shoreline has a smoother shape. The effects of eroding and silting characteristics of the beach on the performance of SAH and DAH are also discussed. The SAH and DAH have similar performance of reducing the flushing time and improving the water exchange in the area behind the artificial headlands compared to TAH. The effect of tidal condition on the flushing time is also discussed. It is suggested that both SAH and DAH are feasible and effective measures to strengthen the water exchange at the cost of an acceptable loss of beach protection.

Published

2018

54. Distribution and variation in proteins of casein micellar fractions response to heat-treatment from five dairy species

Author

Xueheng Sun, Qijing Du, Harvey Ho, Rongwei Han, Rongbo Fan, Y.X. Yang, Runjia Shi, Yu Zhongna, Jun Wang, and Hongning Jiang

Subjects

Hot Temperature, Apolipoprotein B, Proteomics, Analytical Chemistry, fluids and secretions, Tandem Mass Spectrometry, health services administration, Casein, Camel milk, Animals, Distribution (pharmacology), Food science, Micelles, health care economics and organizations, Lipoprotein lipase, biology, Lactoferrin, Chemistry, Caseins, food and beverages, General Medicine, Milk Proteins, Milk, Whey Proteins, Proteome, biology.protein, Chromatography, Liquid, Food Science

Abstract

Casein micelles (CMs) contribute to the physicochemical properties and stability of milk. However, how the proteome of CMs changes following heat treatment has not been elucidated. Here, changes in the proteins of CMs in samples of Holstein, buffalo, yak, goat, and camel milk following heat treatment were investigated using a LC-MS/MS approach. According to the hierarchical clustering results, Holstein, yak, and buffalo milk samples had similar CMs protein components, followed by goat and camel milk samples. Changes in lipoprotein lipase and α-lactalbumin in CMs were dependent on the intensity of heat treatment and were similar among the studied species, whereas changes in κ-casein, lactoferrin, and apolipoprotein A-I differed among different types of milk. These results provide information on the distribution and variations of the proteomes of CMs following heat treatment, which will assist in the identification of proteins that are dissociated and attached to CMs from different dairy species during heat treatment.

Published

2021

55. Measurement of the absolute branching fraction of Λc+→pKS0η decays

Author

B.X. Zhang, Jie Yu, X. L. Luo, S. L. Yang, Z.X. Meng, X. Sun, Yu Lu, K. J. Zhu, Y. Fu, X. L. Gao, L. Y. Dong, K. Begzsuren, T. Holtmann, P. W. Luo, S. Marcello, Y. Zeng, Q.P. Ji, M. Kuemmel, Matthew Glenn Kurth, X. H. Xie, M. Y. Dong, W. P. Wang, Xiaofeng Zhu, J. Z. Zhang, J. J. Song, R. Baldini Ferroli, J. Y. Liu, L. Sun, X. Wang, L. J. Wu, X. Wu, X. F. Cui, L.Q. Qin, Xiongfei Wang, Y. H. Zheng, Cong-Feng Qiao, T. Held, X.R. Chen, F. Bianchi, M. G. Zhao, Y. H. Yang, Evelina Gersabeck, W. J. Zhu, X. X. Ma, X. D. Shi, L. K. Li, Y. F. Wang, H.B. Liu, V. Rodin, Y. J. Mo, A. Sarantsev, O. Bakina, K. Liu, P. Larin, Shan Jin, Q. Liu, X. B. Ji, C. Dong, T. T. Han, Y. Schelhaas, T. Hussain, S. Ahmed, C.D. Fu, X. H. Mo, K.Y. Liu, S. J. Zhao, M. H. Ye, J.Y. Zhang, S. Sosio, F. Yan, Y. H. Zhang, W.G. Li, M. Albrecht, Gang Chen, X. Y. Ma, A. Zhemchugov, D. Y. Liu, I. Uman, W. X. Gong, L. L. Ma, Y.X. Zhao, L. Gong, Libo Guo, H. Cai, X. Pan, B.S. Zou, W. D. Li, O.B. Kolcu, L. Q. Huang, L. Zhao, H. R. Qi, Q. Q. Song, Junfeng Sun, Y. B. Zhao, Jacek Biernat, Q. J. Xu, Y. Gao, I. Denysenko, A. Bortone, Xuanhong Lou, L. G. Xia, A. Amoroso, J.L. Zhang, J.L. Ping, Huanhuan Liu, H. S. Chen, Bingxuan Liu, G. Wilkinson, A. Pathak, Viktor Thorén, Yi Chen, Xujin Yuan, S. B. Liu, X. N. Ma, F.C. Ma, Xiao-Rui Lyu, S. S. Sun, W. S. Cheng, Xiang Zhou, Nasser Kalantar-Nayestanaki, Joachim Pettersson, I. K. Keshk, P.R. Li, A. Dbeyssi, Yao Zhang, F. F. Sui, F.E. Maas, M. H. Gu, R. Kiuchi, P. Patteri, L.H. Wu, C. X. Lin, S. Jaeger, H. N. Li, S.H. Zhu, C.X. Yue, Yue Pan, A. Gilman, Y. G. Gao, W. H. Wang, Meng Wang, Muhammad Irshad, J. Zhu, M. Rump, Lei Zhang, J. Dong, X. S. Qin, R. Farinelli, S. Zhang, Z.T. Sun, M. Shao, Dong E. Liu, J. Q. Li, A. Q. Guo, Guang Zhao, Y. X. Song, X. H. Li, H.X. Yang, B. Wang, Z. J. Chen, Y.X. Yang, K. Peters, W. Imoehl, L. Wollenberg, J. Tang, B. Zhong, Xingchao Dai, C. X. Yu, C. Q. Feng, Zongyuan Wang, M. Scodeggio, J. Bloms, M. Rolo, H. Y. Zhang, C.H. Li, A. Mangoni, F. De Mori, R. E. Mitchell, R. B. de Boer, Shiqun Li, Yunlong Zhang, Y.T. Gu, F. Weidner, Hai-Tian Wang, Y. Yuan, M. Kavatsyuk, W. L. Yuan, Q. Ouyang, F.H. Liu, Yirong Zhu, Zhenjun Xiao, X. L. Ji, X. H. Bai, Y.T. Liang, M.H. Ye, S. S. Fang, C. Y. Guan, F. Nerling, H. C. Shi, R. Kappert, B. Zheng, R. G. Ping, G. Li, T. Y. Qi, Z. Ning, Xingguo Li, Q.M. Ma, Y. B. Liu, F. A. Harris, W. L. Chang, Stephen Lars Olsen, J. B. Jiao, S.P. Wen, Q. Ji, R. Poling, L. M. Gu, C.L. Luo, P. Kiese, J.H. Yin, Bibo Ke, I.B. Nikolaev, Q. Zhao, W. B. Yan, S. Nisar, T. Lenz, D. M. Li, Jianping Zheng, X. Y. Shen, S. Y. Xiao, Z. Y. Yuan, H. Leithoff, M. Ablikim, F. Li, K. Zhu, T. Yu, D.H. Wei, X. K. Zhou, C. J. Tang, G. Felici, Y. G. Xie, B. Kopf, Yuan Hou, Y. K. Heng, S.A. Cetin, M.N. Achasov, M. Pelizaeus, Y. P. Lu, I. Balossino, Anita, S. X. Du, S. Pacetti, S. Gu, R. A. Briere, K. L. He, T. J. Min, J. G. Lu, D. Dedovich, J. F. Hu, Ziyi Wang, Y. X. Tan, Wenbin Qian, N. Huesken, T. Y. Xing, D. Y. Chen, Zhiyong Zhang, Y. H. Tan, G. S. Huang, M. Himmelreich, M. Destefanis, T. Hu, G. Y. Tang, F. Cossio, M. Z. Wang, M. Bertani, C.X. Liu, Jimin Zhao, P. L. Li, S. Qian, Q. An, Ke Li, X. S. Jiang, C. H. Heinz, Y. Fang, T. Liu, L. Koch, Z. A. Liu, Jie Zhao, Z.L. Hou, F. Feldbauer, L. Fava, Zhi Yang, V. Prasad, A. Yuncu, Z. Y. You, Feng Liu, H. M. Hu, X. Y. Zhang, X. L. Wang, Z. A. Zhu, W. C. Yan, J. B. Liu, Y. Ding, Y. Ban, N. Yu. Muchnoi, P. Weidenkaff, F. H. Heinsius, X. Y. Jiang, J. Zhao, G. Mezzadri, Y. J. Sun, Yifan Yang, J. W. Zhang, R. Aliberti, M. M. Ma, L. D. Liu, X. R. Zhou, L. Yang, P. X. Shen, J. L. Li, Z. Wu, Cheng Li, M. Kuessner, C. P. Shen, R. X. Yang, Wei Xu, H. B. Jiang, Jiawei Zhang, P. Adlarson, Zhiqing Zhang, Y. Zhang, J. V. Bennett, W. Gradl, Ruiting Ma, Y. P. Guo, Z. Qian, L.L. Wang, Shuai Liu, H.R. Qi, Z.P. Mao, H. Xiao, Ziyuan Li, W. Shan, A. Rivetti, Tao Sun, J.H. Zou, Z. Jiao, J. Q. Zhang, J. J. Xu, Guangyi Zhang, D. Y. Wang, M. Qi, H. J. Yang, Z.Y. Deng, Jens Soeren Lange, Y. F. Long, R. S. Shi, K. Ravindran, Y. H. Xie, Z.Y. Wang, Zujian Wang, Y.Z. Sun, X.S. Kang, M. Maggiora, Y. Bai, X.Q. Hao, S. Nakhoul, X. L. Lu, L. Yan, F.X. Lu, Magnus Wolke, Lei Zhao, D. C. Shan, Yi Zhang, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, Y. F. Liang, K. Goetzen, C. Z. Yuan, N. Cao, R.P. Guo, S. Han, Jinfei Wu, H. J. Li, Y. J. Xiao, Y.Q. Wang, S. Janchiv, Zhiqing Liu, J.F. Qiu, X. A. Xiong, A. A. Zafar, T. Johansson, J. F. Chang, K. H. Rashid, Tao Luo, Y.D. Wang, R. Kliemt, X. Liu, Yong Huang, C. W. Wang, A. Guskov, B. X. Yu, G.F. Xu, S. J. Chen, G.X. Sun, Andrzej Kupsc, M. L. Chen, C. Zhong, W. M. Song, G. Chelkov, Jianyu Zhang, H. L. Dai, C. F. Redmer, J. D. Lu, C. Schnier, D. Bettoni, Y. Nefedov, A. Khoukaz, X. Cai, X. T. Huang, G. Rong, S. Malde, L. Lavezzi, Haiping Peng, Ke Wang, C. Li, Z. H. Qin, S. Lusso, H.L. Ma, B. L. Wang, Yan Zhang, Y. K. Sun, Z. Huang, S. Spataro, X. P. Xu, Lei Li, H. M. Liu, Y. Jin, Xu Yan, G. F. Cao, R. T. Ma, X D Shi, Y. J. Mao, I. Garzia, L. Zhang, Huihui Liu, J. G. Messchendorp, J. P. Dai, J. Libby, S. F. Zhang, W. Kühn, M. Greco, A. Pitka, G. Cibinetto, John Jake Lane, Guoqiang Yu, K. Schoenning, Niklaus Berger, W.Y. Sun, H. Liang, M. Fritsch, Ke Liu, Q. A. Malik, L. P. Zhou, Y. M. Ma, H. J. Lu, J. Fang, Ch. Rosner, A. Calcaterra, H. B. Li, A. G. Denig, Q. Zhou, H. Muramatsu, A. N. Zhu, Ulrich Wiedner, Tao Zhang, T. Z. Han, Xu Shan, B.J. Liu, Z. G. Zhao, L. Z. Liao, H. H. Zhang, Fang Liu, M. Lellmann, S. Maldaner, M. X. Luo, Dylan Jaide White, Y. Hu, and I. Boyko

Subjects

Physics, Nuclear and High Energy Physics, Particle physics, Annihilation, 010308 nuclear & particles physics, law, Branching fraction, 0103 physical sciences, 010306 general physics, Collider, 01 natural sciences, Symmetry (physics), law.invention

Abstract

Based on 586 p b − 1 of e + e − annihilation data collected at a center-of-mass energy of s = 4.6 GeV with the BESIII detector at the BEPCII collider, the absolute branching fraction of Λ c + → p K S 0 η decays is measured for the first time to be B ( Λ c + → p K S 0 η ) = ( 0.414 ± 0.084 ± 0.028 ) % , where the first uncertainty is statistical and the second is systematic. The result is compatible with a previous CLEO result on the relative branching fraction B ( Λ c + → p K S 0 η ) B ( Λ c + → p K − π + ) , and consistent with theoretical predictions of SU(3) flavor symmetry.

Published

2021

56. Measurement of branching fractions for D meson decaying into $ϕ$ meson and a pseudoscalar meson

Author

J. Zhuang, M. X. Luo, Yuyi Wang, Y. Hu, Xu Zhou, I. Boyko, B.J. Liu, Z. G. Zhao, B. Zhong, L. Z. Liao, H. H. Zhang, Fang Liu, Z. J. Sun, H. J. Li, S. Maldaner, Yunlong Zhang, A. Calcaterra, H. B. Li, A. G. Denig, Q. Zhou, H.Y. Sheng, Michael Papenbrock, F. Yan, Bingxuan Liu, G. Wilkinson, M.G. Alekseev, H. Muramatsu, A. N. Zhu, Ulrich Wiedner, Tao Zhang, Xu Shan, W. S. Cheng, Yao Zhang, S.H. Zhu, A. Gilman, B.S. Zou, X. N. Ma, J. B. Jiao, J.F. Qiu, X. A. Xiong, M. Savrié, H. Liang, L. J. Wu, W. C. Yan, C. Sowa, Y. B. Zhao, M. Qi, Z.T. Sun, Q. Ji, Dahua Zhang, J. G. Lu, Guang Zhao, R. Poling, Xinying Song, A. Sarantsev, F. Li, K. Peters, H. L. Jiang, Jianping Zheng, O. Bakina, K. Liu, Y. J. Mo, M. Kuessner, M. Kuemmel, Matthew Glenn Kurth, G.R. Liao, I. Garzia, Q. Liu, G. Felici, W. Imoehl, A. Zhemchugov, I. Uman, P. Patteri, A. A. Zafar, Q. Gao, Xujin Yuan, J. Dong, M. Fritsch, R.M. Wang, H. J. Yang, Jens Soeren Lange, C. Q. Feng, M. Kavatsyuk, J. Y. Liu, Ke Liu, L.L. Wang, Xingguo Li, X.S. Kang, B. Y. Zhang, L. Zhao, Q. A. Malik, T. Liu, L. Koch, Xiang-Gan Liu, K. H. Rashid, P. W. Luo, H.X. Yang, S. B. Liu, T. Hu, Y.X. Yang, Zongyuan Wang, J. J. Xu, W.G. Li, Q. Zhao, L.Y. Liu, M. Albrecht, L. Fava, T. J. Min, X.Q. Hao, Y. K. Sun, Q.P. Ji, Xiao-Rui Lyu, S. Nisar, L. M. Gu, M. G. Zhao, Y. H. Yang, X. X. Ma, J. Zhu, M.H. Ye, L. Xu, L. P. Zhou, C. J. Tang, L. L. Ma, A. Guskov, W. D. Li, O.B. Kolcu, J.S. Huang, Y. M. Ma, H. J. Lu, A. Yuncu, B. T. Tsednee, Xiaoyu Zhou, L. Gong, Y. Zhang, X. F. Cui, S. J. Chen, X. Y. Shen, S. J. Zhao, T. Y. Qi, J.H. Yin, Y. Schelhaas, Libo Guo, F. Weidner, Yang Zhang, Y. H. Xie, L. K. Li, Y. P. Lu, Shan Jin, Gang Chen, S. Spataro, L. G. Xia, Y. Yuan, J. Fang, Cui Li, D. Dedovich, Y. Fu, Q. J. Xu, M. Destefanis, J. Z. Fan, A. Amoroso, J.L. Ping, X. P. Xu, M. Maggiora, W. B. Yan, T. Y. Xing, Y. G. Gao, H.B. Liu, V. Rodin, Xiongfei Wang, Q. Ouyang, Xuanhong Lou, Viktor Thorén, Nasser Kalantar-Nayestanaki, D. Y. Chen, J. Min, Y. X. Xia, B.X. Zhang, H. R. Qi, Q. Q. Song, Y. H. Yan, C. Morales Morales, Yue Pan, P. X. Shen, C.X. Liu, F.H. Liu, X. B. Ji, K.Y. Liu, S.A. Cetin, Ch. Rosner, A. Dbeyssi, Z. G. Wang, M. Rolo, Lei Zhao, H. Y. Zhang, G. Li, L.H. Wu, J. W. Zhao, S. Pacetti, S. S. Fang, F. Nerling, T. Yu, Z. Wu, X. K. Zhou, H.W. Wen, A. Q. Guo, M.N. Achasov, M. Shao, G. S. Huang, Evelina Gersabeck, Y. Fang, Z. Y. You, Z. A. Zhu, S. F. Zhang, Y. C. Zhu, J. Libby, N. Huesken, Y. Ding, W. Kühn, X.P. Qin, M. Greco, T. Weber, J. Y. Zhang, Magnus Wolke, A. Pitka, G. Cibinetto, X. Wang, Ke Li, Lei Li, B. Kopf, X. Y. Jiang, Zhiqing Zhang, K. L. He, C. F. Redmer, J. D. Lu, M. Y. Dong, Y. F. Liang, W. J. Zhu, F. De Mori, T. Held, I.B. Nikolaev, Y. B. Liu, Meng Wang, D. Bettoni, M. Himmelreich, G. Y. Tang, Y.T. Gu, D. P. Jin, M. Richter, R. Farinelli, H. M. Liu, Z. Ning, C. P. Shen, M. M. Ma, Y. K. Heng, Muhammad Irshad, S. Y. Xiao, X. D. Shi, X. T. Huang, Y. H. Zheng, F. Cossio, Cong-Feng Qiao, J. Bloms, Y.J. Lin, G. Rong, M. Z. Wang, K. Schoenning, Q. Y. Li, Y. Gao, I. Denysenko, Y. Jin, Junfeng Sun, J.L. Zhang, M. Bertani, K. Goetzen, C. Z. Yuan, N. Cao, P. Larin, L.S. Wang, Niklaus Berger, N. Qin, D.H. Wei, F.F. An, F.C. Ma, Jie Zhao, D. X. Lin, Z.L. Hou, Huanhuan Liu, S. S. Sun, J.C. Chen, H. M. Hu, J.H. Zou, A. Mangoni, P.R. Li, X. S. Qin, Jimin Zhao, Y.Z. Sun, S. Han, Xiaozhong Huang, R. Kliemt, Stephen Lars Olsen, B. Wang, T. Lenz, D. M. Li, Y. H. Zhang, Jie Yu, P. L. Li, M. Kurth, Zhenjun Xiao, X. L. Ji, R.P. Guo, G. Mezzadri, J. W. Zhang, F. A. Harris, W. L. Chang, S.P. Wen, A. Mustafa, S. Marcello, R. E. Mitchell, G. F. Cao, J. Chai, G.F. Xu, Andrzej Kupsc, Q.M. Ma, F.E. Maas, S. Qian, Q. An, Y. Zeng, M. L. Chen, H. Leithoff, C.C. Zhang, Y. S. Zhu, F. Feldbauer, K. J. Zhu, Yu Zhang, X D Shi, K. Zhang, Zhiqing Liu, Feng Liu, J. W. Li, M. Pelizaeus, N. Yu. Muchnoi, Y. J. Xiao, X. Y. Zhang, M. Ablikim, J. V. Bennett, Li Yan, Ziyuan Li, W. Shan, Y. J. Mao, Y.Q. Wang, T. Johansson, J. F. Chang, X. Liu, K. Zhu, X. L. Wang, X. L. Gao, Dong E. Liu, Y. G. Xie, S. Ahmed, X. H. Li, J. B. Liu, Q. L. Xiu, Z. Jiao, X. Cai, Li Zhou, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, Xingchao Dai, I. Balossino, S. X. Du, J.C. Li, C. Dong, J.Y. Zhang, S. Sosio, Z. L. Dou, Y. J. Sun, Yifan Yang, J. J. Song, R. Baldini Ferroli, L. Sun, X. L. Luo, L. Yang, L. Zhang, R. Kappert, Joachim Pettersson, Z.Y. Deng, Y. P. Guo, K. Begzsuren, W. P. Wang, F. Bianchi, Z. P. Zhang, C.D. Fu, B. Garillon, T.C. Zhao, Huihui Liu, Xiang Zhou, I. K. Keshk, J. F. Hu, S. Gu, X. H. Mo, X. Tang, C. X. Lin, S. L. Yang, Z.Y. Wang, Zujian Wang, M. Rump, Z.X. Meng, Yu Lu, D. Y. Liu, M. H. Ye, J. G. Messchendorp, Y. Bai, J. P. Dai, S. Nakhoul, Y. T. Tan, W. Gradl, Z. Q. Yang, Zhiyong Zhang, Z.P. Mao, H. Cai, C. W. Wang, G.X. Sun, D. Y. Wang, Tao Luo, B. X. Yu, H. S. Chen, G. Chelkov, H. L. Dai, Jacek Biernat, Y. Nefedov, A. Khoukaz, S. Malde, P.L. Wang, X. N. Li, Haiping Peng, Ke Wang, Z. H. Qin, S. Lusso, H.L. Ma, B. L. Wang, Z. A. Liu, L. Y. Dong, V. Prasad, Y. Ban, P. Weidenkaff, F. H. Heinsius, X. R. Zhou, Cheng Li, F. F. Sui, M. H. Gu, R. Kiuchi, C. X. Yu, Y.T. Liang, B. Zheng, R. G. Ping, A. Rivetti, Z. Gao, J. Q. Zhang, S. L. Niu, F. Y. Li, Y. F. Long, K. Ravindran, Yi Zhang, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, B.C. Ke, C.L. Luo, P. Kiese, Yuan Hou, R. A. Briere, X. S. Jiang, R. X. Yang, Wei Xu, P. Adlarson, Y. F. Wang, T. Hussain, X. Y. Ma, W. X. Gong, X. H. Sun, and L. Lavezzi

Subjects

Nuclear and High Energy Physics, BESIII, Branching fractions, D meson, Hadronic decays, Meson, Astrophysics::High Energy Astrophysical Phenomena, High Energy Physics - Experiment, Branching (polymer chemistry), 01 natural sciences, Pseudoscalar meson, NO, Subatomär fysik, D Meson, 0103 physical sciences, Subatomic Physics, Hadronic Decays, ddc:530, 010306 general physics, Astrophysics::Galaxy Astrophysics, Physics, 010308 nuclear & particles physics, Branching fraction, Branching Fractions, lcsh:QC1-999, Isospin, High Energy Physics::Experiment, Atomic physics, lcsh:Physics

Abstract

The four decay modes D0→ϕπ0, D0→ϕη, D+→ϕπ+, and D+→ϕK+ are studied by using a data sample taken at the centre-of-mass energy s=3.773 GeV with the BESIII detector, corresponding to an integrated luminosity of 2.93 fb$^{−1}$. The branching fractions of the first three decay modes are measured to be B(D0→ϕπ0)=(1.168±0.028±0.028)×10−3, B(D0→ϕη)=(1.81±0.46±0.06)×10−4, and B(D+→ϕπ+)=(5.70±0.05±0.13)×10−3, respectively, where the first uncertainties are statistical and the second are systematic. In addition, the upper limit of the branching fraction for D+→ϕK+ is given to be 2.1×10−5 at the 90% confidence level. The ratio of B(D0→ϕπ0) to B(D+→ϕπ+) is calculated to be (20.49±0.50±0.45)%, which is consistent with the theoretical prediction based on isospin symmetry between these two decay modes.

Published

2019

57. Elastic scattering for the B 8 and Be 7 + Pb 208 systems at near-Coulomb barrier energies

Author

Mazzocco, M. Keeley, N. Boiano, A. Boiano, C. La Commara, M. Manea, C. Parascandolo, C. Pierroutsakou, D. Signorini, C. Strano, E. Torresi, D. Yamaguchi, H. Kahl, D. Acosta, L. Di Meo, P. Fernandez-Garcia, J.P. Glodariu, T. Grebosz, J. Guglielmetti, A. Hirayama, Y. Imai, N. Ishiyama, H. Iwasa, N. Jeong, S.C. Jia, H.M. Kim, Y.H. Kimura, S. Kubono, S. La Rana, G. Lin, C.J. Lotti, P. Marquínez-Durán, G. Martel, I. Miyatake, H. Mukai, M. Nakao, T. Nicoletto, M. Pakou, A. Rusek, K. Sakaguchi, Y. Sánchez-Benítez, A.M. Sava, T. Sgouros, O. Soukeras, V. Soramel, F. Stiliaris, E. Stroe, L. Teranishi, T. Toniolo, N. Wakabayashi, Y. Watanabe, Y.X. Yang, L. Yang, Y.Y. Zhang, H.Q.

Abstract

The elastic scattering of the weakly bound radioactive nuclei B8 and Be7 from a Pb208 target was measured for the first time in the energy range around the Coulomb barrier. The data were analyzed using the optical model and the continuum discretized coupled channels (CDCC) formalisms. The reaction cross sections extracted from the optical model fits clearly indicate a remarkably enhanced reaction probability for the very weakly bound B8 (Sp=137.5keV) compared to similar mass nuclei interacting with the same target nucleus. CDCC calculations assuming a He3+He4 cluster model well described the Be7 experimental elastic scattering angular distributions, whereas the use of a Be7+p cluster model of B8 with an inert Be7 core gave a relatively poor description of the corresponding experimental data, suggesting that this model may be too simplistic and the possibility of core excitation should not be ignored. © 2019 American Physical Society. UK.

Published

2019

58. Observation of a resonant structure in e+e− → ωη and another in e+e− → ωπ0 at center-of-mass energies between 2.00 and 3.08 GeV

Author

J. Zhao, Z. A. Liu, X. Wang, F. De Mori, Magnus Wolke, Y. F. Liang, Y.T. Gu, V. Prasad, T. T. Han, Z.T. Sun, S. Marcello, Y. Zeng, Y. Ban, Xujin Yuan, P. Weidenkaff, F. H. Heinsius, X. L. Gao, T. Y. Xing, D. Y. Chen, W. Imoehl, S. B. Liu, R. Farinelli, J. G. Lu, S. J. Zhao, C.X. Liu, Z.Y. Deng, Y. P. Guo, H. J. Li, Stephen Lars Olsen, R. Kliemt, X. H. Xie, X. R. Zhou, D.H. Wei, G.F. Xu, Andrzej Kupsc, W.Y. Sun, M. L. Chen, T. Lenz, Y. B. Chen, Y. Fang, Z. Y. You, Z. A. Zhu, W. C. Yan, Gang Chen, R. S. Shi, Cheng Li, D. M. Li, Z. Y. Yuan, Xiaofeng Zhu, J. Z. Zhang, J. J. Song, R. Baldini Ferroli, Q. J. Xu, H. Liang, L. Sun, T. Weber, C. Dong, J.Y. Zhang, S. Sosio, M. Qi, F. Li, J.H. Yin, T. Hu, Z.Y. Wang, Zujian Wang, M. Pelizaeus, A. Bortone, Xuanhong Lou, S. Ahmed, C. W. Wang, M. Fritsch, Viktor Thorén, Nasser Kalantar-Nayestanaki, Y. Bai, H. J. Yang, Z. Ning, S. Y. Xiao, A. Yuncu, Jens Soeren Lange, C. P. Shen, L. J. Wu, X. Wu, S.A. Cetin, S. Nakhoul, M.N. Achasov, Yue Pan, O. Bakina, K. Liu, Tao Luo, J.H. Zou, Q. Liu, Y.Z. Sun, L. Yan, J. F. Hu, X.S. Kang, F.X. Lu, G.X. Sun, W. M. Song, Y. X. Tan, P. X. Shen, Z. Wu, L. Y. Dong, X.Q. Hao, Zhiyong Zhang, S. L. Yang, Ke Liu, Q. A. Malik, Zhenjun Xiao, A. Sarantsev, C.L. Luo, X. L. Lu, L. L. Ma, L. Gong, T. Liu, L. Koch, Libo Guo, L.L. Wang, Joachim Pettersson, L. G. Xia, A. Amoroso, J.L. Ping, J. Tang, B. Zhong, X. Y. Jiang, Shuai Liu, R.P. Guo, Jinfei Wu, M. M. Ma, Zhiqing Zhang, F. Feldbauer, X. L. Ji, Z.X. Meng, Yu Lu, P. Kiese, Yuan Hou, M. Rolo, H. Y. Zhang, B. X. Yu, L. Fava, Zhi Yang, L. M. Gu, Yunlong Zhang, A. Dbeyssi, L.H. Wu, R. A. Briere, J. J. Xu, L. P. Zhou, A. Calcaterra, H. B. Li, A. G. Denig, Q. Zhou, Y. J. Mo, R. B. de Boer, Guangyi Zhang, X.P. Qin, Feng Liu, N. Yu. Muchnoi, I. K. Keshk, C. X. Lin, F. F. Sui, M. Rump, M. H. Gu, D. C. Shan, Shan Jin, Xu Yan, Y. M. Ma, H. J. Lu, Z. H. Qin, X D Shi, Q. Ji, Y. J. Mao, R. Kiuchi, R. T. Ma, M. Y. Dong, Y. Zhang, X. S. Jiang, R. Poling, F.H. Liu, I. Denysenko, J. V. Bennett, H. Xiao, Ziyuan Li, Y. H. Zheng, C. X. Yu, Cong-Feng Qiao, B.S. Zou, X. N. Ma, J. B. Jiao, J. Fang, I.B. Nikolaev, G. Li, Jianping Zheng, A. Lavania, W. Shan, C. Zhong, B. Kopf, Z. Jiao, S. F. Zhang, I. Garzia, L. Zhang, R. X. Yang, Wei Xu, H. Muramatsu, A. N. Zhu, Ulrich Wiedner, Y.T. Liang, Tao Zhang, T. Holtmann, W.G. Li, B. Zheng, R. G. Ping, P. Adlarson, K. Peters, J. Y. Liu, M. Savrié, Y. K. Heng, Y.X. Zhao, H. S. Chen, G. Chelkov, Y. B. Zhao, Ch. Rosner, K. L. He, Junfeng Sun, Ziyi Wang, J. Dong, Zhiqing Liu, Q.M. Ma, T. J. Min, F.C. Ma, M. Ablikim, M. Z. Wang, A. Rivetti, M. Bertani, M. Albrecht, Y. H. Zhang, M. Kavatsyuk, Jianyu Zhang, Huihui Liu, H. L. Dai, T. Z. Han, J. Q. Zhang, J. G. Messchendorp, H. C. Shi, Q. Zhao, G. Felici, C.H. Li, S. S. Sun, K. Zhu, M. Kuemmel, Matthew Glenn Kurth, M.H. Ye, Jimin Zhao, X. Y. Shen, P.R. Li, S. Nisar, C. J. Tang, T. Johansson, J. F. Chang, X. Liu, J. Libby, Y. F. Wang, P. L. Li, Y. F. Long, X.R. Chen, K. Ravindran, W. D. Li, O.B. Kolcu, Xu Shan, X. L. Luo, L. Lavezzi, J. P. Dai, Q.P. Ji, M. Destefanis, X. S. Qin, Y. P. Lu, C.D. Fu, D. Dedovich, X. H. Mo, W. Kühn, X. F. Cui, B. Wang, M. Greco, L.Q. Qin, H. R. Qi, X. Cai, C. F. Redmer, J. D. Lu, B.X. Zhang, B. T. Tsednee, C. Schnier, D. Bettoni, L. Z. Liao, Meng Wang, Muhammad Irshad, L. Yang, X. Pan, Y. G. Xie, Ke Wang, C. Li, M. G. Zhao, Y. H. Yang, M. H. Ye, X. X. Ma, J. Zhu, A. Pitka, Y. Ding, Xiongfei Wang, G. Cibinetto, Yi Zhang, R. E. Mitchell, Yan Zhang, Y. K. Sun, Z. Huang, S. Spataro, X. P. Xu, H. B. Jiang, Jiawei Zhang, J. L. Li, John Jake Lane, X. T. Huang, G. S. Huang, Evelina Gersabeck, S. Lusso, H.L. Ma, Guoqiang Yu, G. Rong, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, P. Larin, S. Zhang, I. Balossino, X. Zhou, Y. Fu, Bibo Ke, M. X. Luo, Dylan Jaide White, S. X. Du, W. Gradl, H. Cai, F. A. Harris, W. L. Chang, W. B. Yan, Y. Hu, K. Schoenning, Y. Gao, L. Q. Huang, W. J. Zhu, Jacek Biernat, Y. Schelhaas, X. D. Shi, Y. X. Song, D. Y. Wang, Lei Li, B. L. Wang, H. M. Liu, Y. Jin, H. Leithoff, S. Han, T. Hussain, L. Zhao, I. Boyko, Niklaus Berger, Lei Zhang, X. Y. Ma, W. X. Gong, Y. Nefedov, A. Khoukaz, Ruiting Ma, M. Shao, A. Pathak, S. Pacetti, Z. Qian, G. F. Cao, N. Huesken, Y. C. Zhu, Xiao-Rui Lyu, S. Malde, R. Kappert, B.J. Liu, Y. H. Tan, Ke Li, Haiping Peng, Z. G. Zhao, T. Held, K. Begzsuren, Y. G. Gao, W. H. Wang, H. H. Zhang, Q. Q. Song, S. Gu, Fang Liu, C.X. Yue, S.P. Wen, M. Lellmann, S. Maldaner, Y. J. Xiao, J. Q. Li, A. Q. Guo, Y.Q. Wang, S. Janchiv, J.F. Qiu, X. A. Xiong, L. D. Liu, W. P. Wang, F. Bianchi, J. Bloms, A. A. Zafar, K. H. Rashid, Y.D. Wang, Z.P. Mao, S. Qian, Q. An, A. Guskov, S. J. Chen, X. Y. Zhang, X. L. Wang, J. B. Liu, Y. J. Sun, Yifan Yang, D. Y. Liu, Zongyuan Wang, F. Weidner, Y. Yuan, W. L. Yuan, Q. Ouyang, S. S. Fang, C. Y. Guan, F. Nerling, Y. B. Liu, J.L. Zhang, Huanhuan Liu, F.E. Maas, Dong E. Liu, X. H. Li, L. Wollenberg, Xingchao Dai, Si Li, M. Kuessner, Tao Sun, Y. H. Xie, M. Maggiora, Lei Zhao, K. Goetzen, C. Z. Yuan, N. Cao, A. Zhemchugov, P. W. Luo, I. Uman, L. K. Li, P. Patteri, S. Jaeger, H.X. Yang, H.B. Liu, V. Rodin, Y.X. Yang, X. B. Ji, K.Y. Liu, Bingxuan Liu, G. Wilkinson, M. Himmelreich, G. Y. Tang, W. S. Cheng, Yao Zhang, S.H. Zhu, A. Gilman, Guang Zhao, F. Cossio, Jie Zhao, C. Q. Feng, Hai-Tian Wang, Z.L. Hou, Xingguo Li, H. M. Hu, A. Mangoni, Jie Yu, G. Mezzadri, K. J. Zhu, J. W. Zhang, T. Y. Qi, T. Yu, X. K. Zhou, Wenbin Qian, Nuclear Energy, Research unit Nuclear & Hadron Physics, and Energy and Sustainability Research Institute Groni

Subjects

Physics, Nuclear and High Energy Physics, 010308 nuclear & particles physics, BESIII, Excited ρ states, Excited ω states, 01 natural sciences, Resonance (particle physics), lcsh:QC1-999, NO, law.invention, Nuclear physics, law, 0103 physical sciences, ϕ(2170), Center of mass, 010306 general physics, Collider, lcsh:Physics

Abstract

Born cross sections for the processes e + e − → ω η and e + e − → ω π 0 have been determined for center-of-mass energies between 2.00 and 3.08 GeV with the BESIII detector at the BEPCII collider. The results obtained in this work are consistent with previous measurements but with improved precision. Two resonant structures are observed. In the e + e − → ω η cross sections, a resonance with a mass of ( 2176 ± 24 ± 3 ) MeV / c 2 and a width of ( 89 ± 50 ± 5 ) MeV is observed with a significance of 6.2σ. Its properties are consistent with the ϕ ( 2170 ) . In the e + e − → ω π 0 cross sections, a resonance denoted Y ( 2040 ) is observed with a significance of more than 10σ. Its mass and width are determined to be ( 2034 ± 13 ± 9 ) MeV / c 2 and ( 234 ± 30 ± 25 ) MeV , respectively, where the first uncertainties are statistical and the second ones are systematic.

Published

2021

59. Combinatorial proofs and generalizations of conjectures related to Euler's partition theorem

Author

Jane Y.X. Yang

Subjects

Partition theorem, Conjecture, 010102 general mathematics, Combinatorial proof, 0102 computer and information sciences, Mathematical proof, 01 natural sciences, Combinatorics, symbols.namesake, Integer, 05A17, 05A19, 010201 computation theory & mathematics, Euler's formula, symbols, Bijection, FOS: Mathematics, Discrete Mathematics and Combinatorics, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Mathematics, Analytic proof

Abstract

In a recent work, Andrews gave analytic proofs of two conjectures concerning some variations of two combinatorial identities between partitions of a positive integer into odd parts and partitions into distinct parts discovered by Beck. Subsequently, using the same method as Andrews, Chern presented the analytic proof of another Beck's conjecture relating the gap-free partitions and distinct partitions with odd length. However, the combinatorial interpretations of these conjectures are still unclear and required. In this paper, motivated by Glaisher's bijection, we give the combinatorial proofs of these three conjectures directly or by proving more generalized results., Comment: 14 pages, 4 tables, European Journal of Combinatorics, 2019

Published

2018

60. Measurement of singly Cabibbo-suppressed decays D-0 → π0π0π0, π0π0η, π0ηη and ηηη

Author

M. Ablikim, M.N. Achasov, S. Ahmed, M. Albrecht, A. Amoroso, F.F. An, Q. An, J.Z. Bai, Y. Bai, O. Bakina, R. Baldini Ferroli, Y. Ban, D.W. Bennett, J.V. Bennett, N. Berger, M. Bertani, D. Bettoni, J.M. Bian, F. Bianchi, E. Boger, I. Boyko, R.A. Briere, H. Cai, X. Cai, O. Cakir, A. Calcaterra, G.F. Cao, S.A. Cetin, J. Chai, J.F. Chang, G. Chelkov, G. Chen, H.S. Chen, J.C. Chen, M.L. Chen, P.L. Chen, S.J. Chen, X.R. Chen, Y.B. Chen, X.K. Chu, G. Cibinetto, H.L. Dai, J.P. Dai, A. Dbeyssi, D. Dedovich, Z.Y. Deng, A. Denig, I. Denysenko, M. Destefanis, F. De Mori, Y. Ding, C. Dong, J. Dong, L.Y. Dong, M.Y. Dong, Z.L. Dou, S.X. Du, P.F. Duan, J. Fang, S.S. Fang, Y. Fang, R. Farinelli, L. Fava, S. Fegan, F. Feldbauer, G. Felici, C.Q. Feng, E. Fioravanti, M. Fritsch, C.D. Fu, Q. Gao, X.L. Gao, Y. Gao, Y.G. Gao, Z. Gao, B. Garillon, I. Garzia, K. Goetzen, L. Gong, W.X. Gong, W. Gradl, M. Greco, M.H. Gu, Y.T. Gu, A.Q. Guo, R.P. Guo, Y.P. Guo, Z. Haddadi, S. Han, X.Q. Hao, F.A. Harris, K.L. He, X.Q. He, F.H. Heinsius, T. Held, Y.K. Heng, T. Holtmann, Z.L. Hou, H.M. Hu, T. Hu, Y. Hu, G.S. Huang, J.S. Huang, X.T. Huang, X.Z. Huang, Z.L. Huang, T. Hussain, W. Ikegami Andersson, Q. Ji, Q.P. Ji, X.B. Ji, X.L. Ji, X.S. Jiang, X.Y. Jiang, J.B. Jiao, Z. Jiao, D.P. Jin, S. Jin, Y. Jin, T. Johansson, A. Julin, N. Kalantar-Nayestanaki, X.L. Kang, X.S. Kang, M. Kavatsyuk, B.C. Ke, T. Khan, A. Khoukaz, P. Kiese, R. Kliemt, L. Koch, O.B. Kolcu, B. Kopf, M. Kornicer, M. Kuemmel, M. Kuessner, M. Kuhlmann, A. Kupsc, W. Kühn, J.S. Lange, M. Lara, P. Larin, L. Lavezzi, H. Leithoff, C. Leng, C. Li, Cheng Li, D.M. Li, F. Li, F.Y. Li, G. Li, H.B. Li, H.J. Li, J.C. Li, Jin Li, K.J. Li, Kang Li, Ke Li, Lei Li, P.L. Li, P.R. Li, Q.Y. Li, W.D. Li, W.G. Li, X.L. Li, X.N. Li, X.Q. Li, Z.B. Li, H. Liang, Y.F. Liang, Y.T. Liang, G.R. Liao, D.X. Lin, B. Liu, B.J. Liu, C.X. Liu, D. Liu, F.H. Liu, Fang Liu, Feng Liu, H.B. Liu, H.M. Liu, Huanhuan Liu, Huihui Liu, J.B. Liu, J.Y. Liu, K. Liu, K.Y. Liu, Ke Liu, L.D. Liu, P.L. Liu, Q. Liu, S.B. Liu, X. Liu, Y.B. Liu, Z.A. Liu, Zhiqing Liu, Y.F. Long, X.C. Lou, H.J. Lu, J.G. Lu, Y. Lu, Y.P. Lu, C.L. Luo, M.X. Luo, X.L. Luo, X.R. Lyu, F.C. Ma, H.L. Ma, L.L. Ma, M.M. Ma, Q.M. Ma, T. Ma, X.N. Ma, X.Y. Ma, Y.M. Ma, F.E. Maas, M. Maggiora, Q.A. Malik, Y.J. Mao, Z.P. Mao, S. Marcello, Z.X. Meng, J.G. Messchendorp, G. Mezzadri, J. Min, T.J. Min, R.E. Mitchell, X.H. Mo, Y.J. Mo, C. Morales Morales, N.Yu. Muchnoi, H. Muramatsu, A. Mustafa, Y. Nefedov, F. Nerling, I.B. Nikolaev, Z. Ning, S. Nisar, S.L. Niu, X.Y. Niu, S.L. Olsen, Q. Ouyang, S. Pacetti, Y. Pan, M. Papenbrock, P. Patteri, M. Pelizaeus, J. Pellegrino, H.P. Peng, K. Peters, J. Pettersson, J.L. Ping, R.G. Ping, A. Pitka, R. Poling, V. Prasad, H.R. Qi, M. Qi, S. Qian, C.F. Qiao, N. Qin, X.S. Qin, Z.H. Qin, J.F. Qiu, K.H. Rashid, C.F. Redmer, M. Richter, M. Ripka, M. Rolo, G. Rong, Ch. Rosner, A. Sarantsev, M. Savrié, C. Schnier, K. Schoenning, W. Shan, M. Shao, C.P. Shen, P.X. Shen, X.Y. Shen, H.Y. Sheng, J.J. Song, W.M. Song, X.Y. Song, S. Sosio, C. Sowa, S. Spataro, G.X. Sun, J.F. Sun, L. Sun, S.S. Sun, X.H. Sun, Y.J. Sun, Y.K. Sun, Y.Z. Sun, Z.J. Sun, Z.T. Sun, C.J. Tang, G.Y. Tang, X. Tang, I. Tapan, M. Tiemens, B. Tsednee, I. Uman, G.S. Varner, B. Wang, B.L. Wang, D. Wang, D.Y. Wang, Dan Wang, K. Wang, L.L. Wang, L.S. Wang, M. Wang, Meng Wang, P. Wang, P.L. Wang, W.P. Wang, X.F. Wang, Y. Wang, Y.D. Wang, Y.F. Wang, Y.Q. Wang, Z. Wang, Z.G. Wang, Z.Y. Wang, Zongyuan Wang, T. Weber, D.H. Wei, P. Weidenkaff, S.P. Wen, U. Wiedner, M. Wolke, L.H. Wu, L.J. Wu, Z. Wu, L. Xia, Y. Xia, D. Xiao, H. Xiao, Y.J. Xiao, Z.J. Xiao, Y.G. Xie, Y.H. Xie, X.A. Xiong, Q.L. Xiu, G.F. Xu, J.J. Xu, L. Xu, Q.J. Xu, Q.N. Xu, X.P. Xu, L. Yan, W.B. Yan, W.C. Yan, Y.H. Yan, H.J. Yang, H.X. Yang, L. Yang, Y.H. Yang, Y.X. Yang, M. Ye, M.H. Ye, J.H. Yin, Z.Y. You, B.X. Yu, C.X. Yu, J.S. Yu, C.Z. Yuan, Y. Yuan, A. Yuncu, A.A. Zafar, Y. Zeng, Z. Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.H. Zhang, H.Y. Zhang, J. Zhang, J.L. Zhang, J.Q. Zhang, J.W. Zhang, J.Y. Zhang, J.Z. Zhang, K. Zhang, L. Zhang, S.Q. Zhang, X.Y. Zhang, Y.H. Zhang, Y.T. Zhang, Yang Zhang, Yao Zhang, Yu Zhang, Z.H. Zhang, Z.P. Zhang, Z.Y. Zhang, G. Zhao, J.W. Zhao, J.Y. Zhao, J.Z. Zhao, Lei Zhao, Ling Zhao, M.G. Zhao, Q. Zhao, S.J. Zhao, T.C. Zhao, Y.B. Zhao, Z.G. Zhao, A. Zhemchugov, B. Zheng, J.P. Zheng, Y.H. Zheng, B. Zhong, L. Zhou, X. Zhou, X.K. Zhou, X.R. Zhou, X.Y. Zhou, J. Zhu, K. Zhu, K.J. Zhu, S. Zhu, S.H. Zhu, X.L. Zhu, Y.C. Zhu, Y.S. Zhu, Z.A. Zhu, J. Zhuang, B.S. Zou, J.H. Zou, and Research unit Nuclear & Hadron Physics

Subjects

Nuclear and High Energy Physics, Electron–positron annihilation, Analytical chemistry, 01 natural sciences, NO, Luminosity, Subatomär fysik, Hadronic decays, E(+)E(-), 0103 physical sciences, Subatomic Physics, BESIII, Branching fractions, D0 meson, ddc:530, 010306 general physics, Nuclear Experiment, Physics, D 0 meson, 010308 nuclear & particles physics, Branching fraction, lcsh:QC1-999, D-0 meson, D0meson, High Energy Physics::Experiment, COUPLED-CHANNEL ANALYSIS, lcsh:Physics

Abstract

Physics letters / B B 781, 368 - 375 (2018). doi:10.1016/j.physletb.2018.04.017, Using a data sample of $e^+e^-$ collision data corresponding to an integrated luminosity of 2.93 $fb^{-1}$ collected with the BESIII detector at a center-of-mass energy of $\sqrt{s}= 3.773~GeV$,we search for the singly Cabibbo-suppressed decays $D^{0}\to\pi^{0}\pi^{0}\pi^{0}$, $\pi^{0}\pi^{0}\eta$, $\pi^{0}\eta\eta$ and $\eta\eta\eta$ using the double tag method. The absolute branching fractions are measured to be $\mathcal{B}(D^{0}\to\pi^{0}\pi^{0}\pi^{0}) = (2.0 \pm 0.4 \pm 0.3)\times 10^{-4}$, $\mathcal{B}(D^{0}\to\pi^{0}\pi^{0}\eta) = (3.8 \pm 1.1 \pm 0.7)\times 10^{-4}$ and $\mathcal{B}(D^{0}\to\pi^{0}\eta\eta) = (7.3 \pm 1.6 \pm 1.5)\times 10^{-4}$ with the statistical significances of $4.8\sigma$, $3.8\sigma$ and $5.5\sigma$, respectively, where the first uncertainties are statistical and the second ones systematic. No significant signal of $D^{0}\to\eta\eta\eta$ is found, and the upper limit on its decay branching fraction is set to be $\mathcal{B}(D^{0}\to\eta\eta\eta) < 1.3 \times 10^{-4}$ at the $90\%$ confidence level., Published by North-Holland Publ., Amsterdam

Published

2018

61. Changes in serum metabolites in response to ingested colostrum and milk in neonatal calves, measured by nuclear magnetic resonance-based metabolomics analysis

Author

Y.X. Yang, G.L. Cheng, X.C. Pan, H.L. Zhao, Y.X. Qi, X.W. Zhao, and D.W. Huang

Subjects

0301 basic medicine, Male, Magnetic Resonance Spectroscopy, animal diseases, medicine.medical_treatment, Metabolite, Passive immunity, Biology, Immunoglobulin G, 03 medical and health sciences, chemistry.chemical_compound, fluids and secretions, Nuclear magnetic resonance, Valine, Genetics, medicine, Ingestion, Animals, Metabolomics, Lactose, Colostrum, 0402 animal and dairy science, food and beverages, 04 agricultural and veterinary sciences, 040201 dairy & animal science, Small intestine, 030104 developmental biology, medicine.anatomical_structure, Milk, chemistry, Animals, Newborn, biology.protein, Animal Science and Zoology, Cattle, Female, Food Science

Abstract

Uptake of colostrum is of central importance for establishing a passive immunity transfer in neonatal calves. Studies of absorption and transmission of colostral immunoglobulins have been widely reported; however, changes in the serum in response to the absorption of colostral components in neonatal calves have not been completely characterized. Here, a nuclear magnetic resonance-based metabolomics approach was used to investigate the changes in metabolites in ingested colostrum, milk, and serum after neonatal calves were fed colostrum or milk. Twenty-seven neonatal male Holstein calves were assigned to 1 of the following groups: (1) calves not fed colostrum or milk and slaughtered approximately 2 h after birth (control group, n = 6), (2) calves fed colostrum at 1 to 2 h after birth and slaughtered 8 h after birth (n = 6), (3) calves fed 2 colostrum meals (at 1-2 and 10-12 h after birth) and slaughtered 24 h after birth (n = 6), (4) calves fed 3 colostrum meals (at 1-2, 10-12, and 22-24 h after birth) and slaughtered 36 h after birth (n = 6), or (5) calves fed 2 milk meals (1-2 and 10-12 h after birth) and slaughtered 24 h after birth (n = 3). Concentrations of valine, leucine, lactate, lysine, and isoleucine were higher and concentrations of lactose were lower in the groups fed colostrum and milk compared with groups not fed colostrum and milk, respectively. Metabolite changes between groups fed or not fed colostrum and milk were similar and may reflect the primary metabolic requirements of ingestion by the small intestine of neonatal calves. Concentrations of serum metabolites choline, valine, leucine, and glutamate were higher in the serum of calves that received colostrum compared with control calves. Furthermore, concentrations of serum phenylalanine, valine, and glutamate were significantly higher, whereas serum concentrations of citrate and very low density lipoproteins were lower in calves that received colostrum compared with calves fed milk. Our results indicate that concentrations of leucine, valine, and glutamate, which were higher in the calves that ingested colostrum, may transfer into the bloodstream, and that these metabolites are associated with health benefits in the neonatal calves that received colostrum. These findings provide novel information to help us understand the mechanism by which colostrum components are metabolized and absorbed in the small intestine and then transferred into bloodstream of neonatal calves.

Published

2017

62. WHAT ARE THE GAP BETWEEN GERIATRICIANS AND ONCOLOGIST? A SURVEY OF DOCTOR AWARENESS OF MEDICAL CARE AMONG ELDERLY PATIENTS WITH CANCER IN SOUTHWEST CHINA

Author

L.-X. Wang, Z.M. Meng, S.S. Nie, B. Xiang, J. Li, Q.Q. Sun, H. Qin, Y.L. Gong, C.C. Pan, C. Yi, Y.X. Yang, and S. Wang

Abstract

Objectives: Old patients with cancer are a great challenge to physicians. This study investigated the similarities and differences in the respective opinions of geriatricians and oncologists with regard to clinical practice among elderly patients with cancer in south west China. Design, Setting, Participants and Measurements: Doctors from five local public hospitals of Sichuan were surveyed with a questionnaire via face-to-face interview. The ratio of geriatricians to oncologists’ was1:1. The questionnaire addressed respondents’ demographic characteristics and was composed of 11 multiple-choice questions and a clinical scenario. Results: The respondents included 64 oncologists and geriatricians, respectively. More than forty percent participants believed that current treatments were under-treatment. «Opinion of family members» was the top one reason for under-treatment in both groups, more oncologist choice «comorbidity» as cause of insufficient treatment than geriatricians (p=0.001). Age (57.03%) was the fifth effect factor impacting on treatment decision except for physical function (81.25%), comorbidity (71.09%) and cancer itself. Physical function, comorbidity and age between 65-84, geriatrician and oncologist did have different attitude. Conclusions: The attitude to physical function and comorbidity were the main difference between geriatrician and oncologist for their clinical decisions. A workshop should be set up to optimize the treatment proceedings.

Published

2015

63. A novel 3-base pair deletion of the CRYAA gene identified in a large Chinese pedigree featuring autosomal dominant congenital perinuclear cataract

Author

Hui-rong Shi, J.M. Dong, Xiangdong Kong, J. Li-Ling, Ning Liu, J. Liu, Z.H. Zhao, and Y.X. Yang

Subjects

Adult, Male, China, Heterozygote, Han chinese, Base pair, Molecular Sequence Data, Prenatal diagnosis, Disease, Gene mutation, Cataract, CRYAA gene, Asian People, Genetics, Humans, Medicine, Base Pairing, Molecular Biology, Genes, Dominant, Sequence Deletion, Base Sequence, business.industry, Fetal period, Infant, Newborn, Computational Biology, General Medicine, Crystallins, Perinuclear cataract, Pedigree, Female, business, Follow-Up Studies

Abstract

Congenital cataract is caused by reduced transparency of the lens resulting from metabolic disorders during the fetal period. The disease shows great heterogeneity both clinically and genetically. We identified a 4-generation ethnic Han Chinese family affected by autosomal dominant congenital perinuclear cataract. The patients underwent full clinical and ophthalmologic examinations to rule out any concomitant disorders. Blood samples were collected and genomic DNA was extracted. Potential mutations in the candidate gene alpha A crystallin (CRYAA) were screened. Prenatal diagnosis was then provided for a fetus of the affected proband by chorionic villus sampling. In all patients, DNA sequencing of the CRYAA gene revealed a novel 3-bp deletion mutation in exon 3 (c.246_248delCGC), which led to deletion of codon 117 encoding arginine (p.117delR) in the peptide chain. The same mutation was not found among unaffected and healthy individuals. Bioinformatic analysis revealed that although the c.246_248delCGC is an 'in-frame' mutation, removal of arginine resulted in a significant change in the protein structure. The fetus did not possess this mutation and was confirmed to be healthy at 1-year follow-up. A novel disease-causing mutation, c.246_248delCGC (p.117delR), of the CRYAA gene has been identified in a Chinese family with autosomal-type perinuclear congenital cataracts. This is also the first report of prenatal diagnosis of this type of congenital cataract.

Published

2015

64. Measurement of cross sections of the interactions e+e−→ ϕϕω and e+e−→ ϕϕϕ at center-of-mass energies from 4.008 to 4.600 GeV

Author

M. Ablikim, M.N. Achasov, S. Ahmed, X.C. Ai, O. Albayrak, M. Albrecht, D.J. Ambrose, A. Amoroso, F.F. An, Q. An, J.Z. Bai, O. Bakina, R. Baldini Ferroli, Y. Ban, D.W. Bennett, J.V. Bennett, N. Berger, M. Bertani, D. Bettoni, J.M. Bian, F. Bianchi, E. Boger, I. Boyko, R.A. Briere, H. Cai, X. Cai, O. Cakir, A. Calcaterra, G.F. Cao, S.A. Cetin, J. Chai, J.F. Chang, G. Chelkov, G. Chen, H.S. Chen, J.C. Chen, M.L. Chen, S. Chen, S.J. Chen, X. Chen, X.R. Chen, Y.B. Chen, X.K. Chu, G. Cibinetto, H.L. Dai, J.P. Dai, A. Dbeyssi, D. Dedovich, Z.Y. Deng, A. Denig, I. Denysenko, M. Destefanis, F. De Mori, Y. Ding, C. Dong, J. Dong, L.Y. Dong, M.Y. Dong, Z.L. Dou, S.X. Du, P.F. Duan, J.Z. Fan, J. Fang, S.S. Fang, X. Fang, Y. Fang, R. Farinelli, L. Fava, F. Feldbauer, G. Felici, C.Q. Feng, E. Fioravanti, M. Fritsch, C.D. Fu, Q. Gao, X.L. Gao, Y. Gao, Z. Gao, I. Garzia, K. Goetzen, L. Gong, W.X. Gong, W. Gradl, M. Greco, M.H. Gu, Y.T. Gu, Y.H. Guan, A.Q. Guo, L.B. Guo, R.P. Guo, Y. Guo, Y.P. Guo, Z. Haddadi, A. Hafner, S. Han, X.Q. Hao, F.A. Harris, K.L. He, F.H. Heinsius, T. Held, Y.K. Heng, T. Holtmann, Z.L. Hou, C. Hu, H.M. Hu, T. Hu, Y. Hu, G.S. Huang, J.S. Huang, X.T. Huang, X.Z. Huang, Z.L. Huang, T. Hussain, W. Ikegami Andersson, Q. Ji, Q.P. Ji, X.B. Ji, X.L. Ji, L.W. Jiang, X.S. Jiang, X.Y. Jiang, J.B. Jiao, Z. Jiao, D.P. Jin, S. Jin, T. Johansson, A. Julin, N. Kalantar-Nayestanaki, X.L. Kang, X.S. Kang, M. Kavatsyuk, B.C. Ke, P. Kiese, R. Kliemt, B. Kloss, O.B. Kolcu, B. Kopf, M. Kornicer, A. Kupsc, W. Kühn, J.S. Lange, M. Lara, P. Larin, H. Leithoff, C. Leng, C. Li, Cheng Li, D.M. Li, F. Li, F.Y. Li, G. Li, H.B. Li, H.J. Li, J.C. Li, Jin Li, K. Li, Lei Li, P.R. Li, Q.Y. Li, T. Li, W.D. Li, W.G. Li, X.L. Li, X.N. Li, X.Q. Li, Y.B. Li, Z.B. Li, H. Liang, Y.F. Liang, Y.T. Liang, G.R. Liao, D.X. Lin, B. Liu, B.J. Liu, C.X. Liu, D. Liu, F.H. Liu, Fang Liu, Feng Liu, H.B. Liu, H.H. Liu, H.M. Liu, J. Liu, J.B. Liu, J.P. Liu, J.Y. Liu, K. Liu, K.Y. Liu, L.D. Liu, P.L. Liu, Q. Liu, S.B. Liu, X. Liu, Y.B. Liu, Y.Y. Liu, Z.A. Liu, Zhiqing Liu, H. Loehner, Y.F. Long, X.C. Lou, H.J. Lu, J.G. Lu, Y. Lu, Y.P. Lu, C.L. Luo, M.X. Luo, T. Luo, X.L. Luo, X.R. Lyu, F.C. Ma, H.L. Ma, L.L. Ma, M.M. Ma, Q.M. Ma, T. Ma, X.N. Ma, X.Y. Ma, Y.M. Ma, F.E. Maas, M. Maggiora, Q.A. Malik, Y.J. Mao, Z.P. Mao, S. Marcello, J.G. Messchendorp, G. Mezzadri, J. Min, T.J. Min, R.E. Mitchell, X.H. Mo, Y.J. Mo, C. Morales Morales, G. Morello, N.Yu. Muchnoi, H. Muramatsu, P. Musiol, Y. Nefedov, F. Nerling, I.B. Nikolaev, Z. Ning, S. Nisar, S.L. Niu, X.Y. Niu, S.L. Olsen, Q. Ouyang, S. Pacetti, Y. Pan, P. Patteri, M. Pelizaeus, H.P. Peng, K. Peters, J. Pettersson, J.L. Ping, R.G. Ping, R. Poling, V. Prasad, H.R. Qi, M. Qi, S. Qian, C.F. Qiao, L.Q. Qin, N. Qin, X.S. Qin, Z.H. Qin, J.F. Qiu, K.H. Rashid, C.F. Redmer, M. Ripka, G. Rong, Ch. Rosner, X.D. Ruan, A. Sarantsev, M. Savrié, C. Schnier, K. Schoenning, W. Shan, M. Shao, C.P. Shen, P.X. Shen, X.Y. Shen, H.Y. Sheng, W.M. Song, X.Y. Song, S. Sosio, S. Spataro, G.X. Sun, J.F. Sun, S.S. Sun, X.H. Sun, Y.J. Sun, Y.Z. Sun, Z.J. Sun, Z.T. Sun, C.J. Tang, X. Tang, I. Tapan, E.H. Thorndike, M. Tiemens, I. Uman, G.S. Varner, B. Wang, B.L. Wang, D. Wang, D.Y. Wang, K. Wang, L.L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, W. Wang, W.P. Wang, X.F. Wang, Y. Wang, Y.D. Wang, Y.F. Wang, Y.Q. Wang, Z. Wang, Z.G. Wang, Z.H. Wang, Z.Y. Wang, Zongyuan Wang, T. Weber, D.H. Wei, P. Weidenkaff, S.P. Wen, U. Wiedner, M. Wolke, L.H. Wu, L.J. Wu, Z. Wu, L. Xia, L.G. Xia, Y. Xia, D. Xiao, H. Xiao, Z.J. Xiao, Y.G. Xie, Y.H. Xie, Q.L. Xiu, G.F. Xu, J.J. Xu, L. Xu, Q.J. Xu, Q.N. Xu, X.P. Xu, L. Yan, W.B. Yan, W.C. Yan, Y.H. Yan, H.J. Yang, H.X. Yang, L. Yang, Y.X. Yang, M. Ye, M.H. Ye, J.H. Yin, Z.Y. You, B.X. Yu, C.X. Yu, J.S. Yu, C.Z. Yuan, Y. Yuan, A. Yuncu, A.A. Zafar, Y. Zeng, Z. Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.H. Zhang, H.Y. Zhang, J. Zhang, J.J. Zhang, J.L. Zhang, J.Q. Zhang, J.W. Zhang, J.Y. Zhang, J.Z. Zhang, K. Zhang, L. Zhang, S.Q. Zhang, X.Y. Zhang, Y. Zhang, Y.H. Zhang, Y.N. Zhang, Y.T. Zhang, Yu Zhang, Z.H. Zhang, Z.P. Zhang, Z.Y. Zhang, G. Zhao, J.W. Zhao, J.Y. Zhao, J.Z. Zhao, Lei Zhao, Ling Zhao, M.G. Zhao, Q. Zhao, Q.W. Zhao, S.J. Zhao, T.C. Zhao, Y.B. Zhao, Z.G. Zhao, A. Zhemchugov, B. Zheng, J.P. Zheng, W.J. Zheng, Y.H. Zheng, B. Zhong, L. Zhou, X. Zhou, X.K. Zhou, X.R. Zhou, X.Y. Zhou, K. Zhu, K.J. Zhu, S. Zhu, S.H. Zhu, X.L. Zhu, Y.C. Zhu, Y.S. Zhu, Z.A. Zhu, J. Zhuang, L. Zotti, B.S. Zou, J.H. Zou, and İstanbul Arel Üniversitesi

Subjects

Nuclear and High Energy Physics, BESIII, детектор, e+e- annihilation, Electron–positron annihilation, 01 natural sciences, NO, law.invention, Nuclear physics, Cross section (physics), law, 0103 physical sciences, Cross section, e+e−annihilation, Triple quarkonia, 010306 general physics, Collider, Physics, Annihilation, 010308 nuclear & particles physics, e+e− annihilation, lcsh:QC1-999, BEPCII, коллайдер, e+e? annihilation, Center of mass, lcsh:Physics

Abstract

Using data samples collected with the BESIII detector at the BEPCII collider at six center-of-mass energies between 4.008 and 4.600 GeV, we observe the processes e + e − → ϕ ϕ ω and e + e − → ϕ ϕ ϕ . The Born cross sections are measured and the ratio of the cross sections σ ( e + e − → ϕ ϕ ω ) / σ ( e + e − → ϕ ϕ ϕ ) is estimated to be 1.75 ± 0.22 ± 0.19 averaged over six energy points, where the first uncertainty is statistical and the second is systematic. The results represent first measurements of these interactions.

Published

2017

65. Targeting effect of microRNA on CD133 and its impact analysis on proliferation and invasion of glioma cells

Author

Y.X. Yang, W.C. Yao, S.L. Mou, C. Zhao, Z.G. Ma, and Y.H. Zhang

Subjects

0301 basic medicine, Untranslated region, Nervous System Neoplasms, Apoptosis, Transfection, 03 medical and health sciences, Cell Movement, Cell Line, Tumor, Glioma, microRNA, Genetics, medicine, Humans, Luciferase, AC133 Antigen, RNA, Messenger, 3' Untranslated Regions, neoplasms, Molecular Biology, Cell Proliferation, Messenger RNA, biology, Chemistry, Cell Cycle, General Medicine, medicine.disease, In vitro, Gene Expression Regulation, Neoplastic, MicroRNAs, 030104 developmental biology, embryonic structures, Cancer research, biology.protein, CREB1

Abstract

MiR-200b, a member of the microRNA-200 family, has been identified to be capable of suppressing glioma cell growth through targeting CREB1 or CD133. However, whether miR-200b affects the biological behavior (proliferation, invasion, and migration) of glioma cells is poorly understood. The aim of this study was to evaluate the effect of miR-200b on the biological behavior of glioma cells in vitro. MiRNA-200b mimics, miRNA-200b inhibitor, and mimic control were transfected into conventionally cultured glioma U251 cells, followed by measuring the expression of miR-200b and CD133 in transfected cells by RT-PCR; effect of miR-200b on CD133 mRNA 3'-UTR luciferase activity by luciferase reporter assay; proliferation activity of transfected U251 cells by MTT method; and changes in U251 cell invasion and migration by Transwell method after transfection. Compared to that in the miRNA-200b inhibitor, mimic control, and blank control groups, miRNA-200b expression was significantly increased and CD133 mRNA expression was significantly decreased in the mimic miRNA-200b group in a time-dependent manner (P < 0.05). Meanwhile, dual luciferase reporter assay showed that miR-200b could inhibit CD133 activity through binding to the 3'-UTR of CD133 mRNA (P < 0.05). Furthermore, the proliferation activity and invasion and migration abilities of U251 cells transfected with miRNA-200b mimic were significantly decreased (P < 0.05). In conclusion, overexpression of miR-200b inhibited the proliferation, invasion, and migration of glioma cells possibly through targeting CD133.

Published

2017

66. Measurement of the D→K−π+ strong phase difference in ψ(3770)→D0D¯0

Author

M. Ablikim, M.N. Achasov, X.C. Ai, O. Albayrak, M. Albrecht, D.J. Ambrose, F.F. An, Q. An, J.Z. Bai, R. Baldini Ferroli, Y. Ban, D.W. Bennett, J.V. Bennett, M. Bertani, J.M. Bian, E. Boger, O. Bondarenko, I. Boyko, S. Braun, R.A. Briere, H. Cai, X. Cai, O. Cakir, A. Calcaterra, G.F. Cao, S.A. Cetin, J.F. Chang, G. Chelkov, G. Chen, H.S. Chen, J.C. Chen, M.L. Chen, S.J. Chen, X. Chen, X.R. Chen, Y.B. Chen, H.P. Cheng, X.K. Chu, Y.P. Chu, D. Cronin-Hennessy, H.L. Dai, J.P. Dai, D. Dedovich, Z.Y. Deng, A. Denig, I. Denysenko, M. Destefanis, W.M. Ding, Y. Ding, C. Dong, J. Dong, L.Y. Dong, M.Y. Dong, S.X. Du, J.Z. Fan, J. Fang, S.S. Fang, Y. Fang, L. Fava, C.Q. Feng, C.D. Fu, O. Fuks, Q. Gao, Y. Gao, C. Geng, K. Goetzen, W.X. Gong, W. Gradl, M. Greco, M.H. Gu, Y.T. Gu, Y.H. Guan, L.B. Guo, T. Guo, Y.P. Guo, Z. Haddadi, Y.L. Han, F.A. Harris, K.L. He, M. He, Z.Y. He, T. Held, Y.K. Heng, Z.L. Hou, C. Hu, H.M. Hu, J.F. Hu, T. Hu, G.M. Huang, G.S. Huang, H.P. Huang, J.S. Huang, L. Huang, X.T. Huang, Y. Huang, T. Hussain, C.S. Ji, Q. Ji, Q.P. Ji, X.B. Ji, X.L. Ji, L.L. Jiang, L.W. Jiang, X.S. Jiang, J.B. Jiao, Z. Jiao, D.P. Jin, S. Jin, T. Johansson, A. Julin, N. Kalantar-Nayestanaki, X.L. Kang, X.S. Kang, M. Kavatsyuk, B. Kloss, B. Kopf, M. Kornicer, W. Kuehn, A. Kupsc, W. Lai, J.S. Lange, M. Lara, P. Larin, M. Leyhe, C.H. Li, Cheng Li, Cui Li, D. Li, D.M. Li, F. Li, G. Li, H.B. Li, J.C. Li, Jin Li, K. Li, Lei Li, P.R. Li, Q.J. Li, T. Li, W.D. Li, W.G. Li, X.L. Li, X.N. Li, X.Q. Li, Z.B. Li, H. Liang, Y.F. Liang, Y.T. Liang, D.X. Lin, B.J. Liu, C.L. Liu, C.X. Liu, F.H. Liu, Fang Liu, Feng Liu, H.B. Liu, H.H. Liu, H.M. Liu, J. Liu, J.P. Liu, K. Liu, K.Y. Liu, P.L. Liu, Q. Liu, S.B. Liu, X. Liu, Y.B. Liu, Z.A. Liu, Zhiqiang Liu, Zhiqing Liu, H. Loehner, X.C. Lou, G.R. Lu, H.J. Lu, H.L. Lu, J.G. Lu, Y. Lu, Y.P. Lu, C.L. Luo, M.X. Luo, T. Luo, X.L. Luo, M. Lv, X.R. Lyu, F.C. Ma, H.L. Ma, Q.M. Ma, S. Ma, T. Ma, X.Y. Ma, F.E. Maas, M. Maggiora, Q.A. Malik, Y.J. Mao, Z.P. Mao, J.G. Messchendorp, J. Min, T.J. Min, R.E. Mitchell, X.H. Mo, Y.J. Mo, H. Moeini, C. Morales Morales, K. Moriya, N.Yu. Muchnoi, H. Muramatsu, Y. Nefedov, F. Nerling, I.B. Nikolaev, Z. Ning, S. Nisar, X.Y. Niu, S.L. Olsen, Q. Ouyang, S. Pacetti, M. Pelizaeus, H.P. Peng, K. Peters, J.L. Ping, R.G. Ping, R. Poling, M. Qi, S. Qian, C.F. Qiao, L.Q. Qin, N. Qin, X.S. Qin, Y. Qin, Z.H. Qin, J.F. Qiu, K.H. Rashid, C.F. Redmer, M. Ripka, G. Rong, X.D. Ruan, A. Sarantsev, K. Schoenning, S. Schumann, W. Shan, M. Shao, C.P. Shen, X.Y. Shen, H.Y. Sheng, M.R. Shepherd, W.M. Song, X.Y. Song, S. Spataro, B. Spruck, G.X. Sun, J.F. Sun, S.S. Sun, Y.J. Sun, Y.Z. Sun, Z.J. Sun, Z.T. Sun, C.J. Tang, X. Tang, I. Tapan, E.H. Thorndike, M. Tiemens, D. Toth, M. Ullrich, I. Uman, G.S. Varner, B. Wang, D. Wang, D.Y. Wang, K. Wang, L.L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, Q.J. Wang, S.G. Wang, W. Wang, X.F. Wang, Y.D. Wang, Y.F. Wang, Y.Q. Wang, Z. Wang, Z.G. Wang, Z.H. Wang, Z.Y. Wang, D.H. Wei, J.B. Wei, P. Weidenkaff, S.P. Wen, M. Werner, U. Wiedner, M. Wolke, L.H. Wu, N. Wu, Z. Wu, L.G. Xia, Y. Xia, D. Xiao, Z.J. Xiao, Y.G. Xie, Q.L. Xiu, G.F. Xu, L. Xu, Q.J. Xu, Q.N. Xu, X.P. Xu, Z. Xue, L. Yan, W.B. Yan, W.C. Yan, Y.H. Yan, H.X. Yang, L. Yang, Y. Yang, Y.X. Yang, H. Ye, M. Ye, M.H. Ye, B.X. Yu, C.X. Yu, H.W. Yu, J.S. Yu, S.P. Yu, C.Z. Yuan, W.L. Yuan, Y. Yuan, A. Yuncu, A.A. Zafar, A. Zallo, S.L. Zang, Y. Zeng, B.X. Zhang, B.Y. Zhang, C. Zhang, C.B. Zhang, C.C. Zhang, D.H. Zhang, H.H. Zhang, H.Y. Zhang, J.J. Zhang, J.Q. Zhang, J.W. Zhang, J.Y. Zhang, J.Z. Zhang, S.H. Zhang, X.J. Zhang, X.Y. Zhang, Y. Zhang, Y.H. Zhang, Z.H. Zhang, Z.P. Zhang, Z.Y. Zhang, G. Zhao, J.W. Zhao, Lei Zhao, Ling Zhao, M.G. Zhao, Q. Zhao, Q.W. Zhao, S.J. Zhao, T.C. Zhao, X.H. Zhao, Y.B. Zhao, Z.G. Zhao, A. Zhemchugov, B. Zheng, J.P. Zheng, Y.H. Zheng, B. Zhong, L. Zhou, Li Zhou, X. Zhou, X.K. Zhou, X.R. Zhou, X.Y. Zhou, K. Zhu, K.J. Zhu, X.L. Zhu, Y.C. Zhu, Y.S. Zhu, Z.A. Zhu, J. Zhuang, B.S. Zou, and J.H. Zou

Subjects

Phase difference, Physics, Nuclear and High Energy Physics, media_common.quotation_subject, Electron–positron annihilation, Quantum mechanics, Analytical chemistry, Pi, CP violation, 7. Clean energy, Asymmetry, media_common

Abstract

We study D 0 D ¯ 0 pairs produced in e + e − collisions at s = 3.773 GeV using a data sample of 2.92 fb−1 collected with the BESIII detector. We measured the asymmetry A K π CP of the branching fractions of D → K − π + in CP-odd and CP-even eigenstates to be ( 12.7 ± 1.3 ± 0.7 ) × 10 − 2 . A K π CP can be used to extract the strong phase difference δ K π between the doubly Cabibbo-suppressed process D ¯ 0 → K − π + and the Cabibbo-favored process D 0 → K − π + . Using world-average values of external parameters, we obtain cos δ K π = 1.02 ± 0.11 ± 0.06 ± 0.01 . Here, the first and second uncertainties are statistical and systematic, respectively, while the third uncertainty arises from the external parameters. This is the most precise measurement of δ K π to date.

Published

2014

67. Photocatalytic properties of Bi2O2CO3 nanosheets synthesized via a surfactant-assisted hydrothermal method

Author

Hong Liang, Y.X. Yang, J.C. Tang, and M. Ge

Subjects

Materials science, Diffuse reflectance infrared fourier transform, Scanning electron microscope, Mechanical Engineering, Inorganic chemistry, Condensed Matter Physics, Hydrothermal circulation, chemistry.chemical_compound, chemistry, Pulmonary surfactant, Chemical engineering, Mechanics of Materials, Transmission electron microscopy, Photocatalysis, General Materials Science, Sodium dodecyl sulfate, Photodegradation

Abstract

Bi2O2CO3 nanosheets were synthesized via a facile sodium dodecyl sulfate (SDS)-assisted hydrothermal process. X-Ray diffraction (XRD), field-emission scanning electron microscopy (FESEM), transmission electron microscopy (TEM), Brunauer–Emmett–Teller (BET) surface area analysis and UV-Vis diffuse reflectance spectroscopy techniques were used to investigate the phase structure, morphology and optical properties of the Bi2O2CO3 products. The SDS surfactant played an important role in the formation of Bi2O2CO3 nanosheets. As-synthesized Bi2O2CO3 nanosheets exhibited excellent photocatalytic activity for RhB degradation under irradiation with simulated sunlight. O2 − radicals are considered to be the dominant active oxygen species in the photodegradation process.

Published

2013

68. Facile synthesis of monodisperse CdS nanospheres capped with allyl thiourea

Author

Dongmei Zhang, Y. S. Zhang, C. J. Tang, Y.X. Yang, and Fengjian Su

Subjects

Photoluminescence, Materials science, Scanning electron microscope, Mechanical Engineering, Dispersity, Inorganic chemistry, Nanoparticle, Condensed Matter Physics, Photochemistry, Hydrothermal circulation, chemistry.chemical_compound, Thiourea, chemistry, Mechanics of Materials, Transmission electron microscopy, Reagent, General Materials Science

Abstract

Highly monodisperse CdS nanospheres capped with allyl thiourea were synthesised via a facile hydrothermal method without any surfactant. The products were characterised by X-ray diffraction, scanning electron microscopy, transmission electron microscopy, photoluminescence and Fourier transform infrared spectra. The results show that CdS nanospheres have the diameters of about 300 nm and are composed of nanoplates. The reaction parameters, such as the concentration of the reagent, the ratio of sulphide to cadmium source and the cadmium salt type that affected the CdS morphology, were investigated systematically. Based on the experiments, the possible formation mechanism for the nanospheres is ascribed to anisotropic growth of the nanoparticles and self-assembly caused by the lowest surface tension. The photoluminescence spectrum of the nanospheres shows about 60 nm blue shift compared with that of bulk CdS.

Published

2013

69. Effects of duodenal infusion of free α-linolenic acid on the plasma and milk proteome of lactating dairy cows

Author

T.J. Yuan, P. Sun, Jiaqi Wang, L.Y. Zhou, J.H. Yang, Y.X. Yang, and Dengpan Bu

Subjects

medicine.medical_specialty, Linolenic acid, Duodenum, proteome, SF1-1100, Mass Spectrometry, chemistry.chemical_compound, Western blot, Internal medicine, Lactation, medicine, Animals, Electrophoresis, Gel, Two-Dimensional, plasma, Gel electrophoresis, milk, biology, medicine.diagnostic_test, Dose-Response Relationship, Drug, Chemistry, alpha-Linolenic acid, dairy cow, Haptoglobin, Albumin, alpha-Linolenic Acid, food and beverages, Animal culture, Endocrinology, medicine.anatomical_structure, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, biology.protein, Animal Science and Zoology, Cattle, Female, linolenic acid

Abstract

This study is an exploratory analysis for understanding the effect of a duodenal infusion of an α-linolenic acid (LNA) on the plasma and milk proteome of lactating dairy cows. Four primiparous Holstein cows were fitted with duodenal cannulas and received 0, 100, 200, 300 and 400 g/day of LNA in a two-treatment crossover design. Blood and milk were collected for determination of protein composition by two-dimensional gel electrophoresis. Alteration of protein spots was detected and identified using matrix-assisted laser desorption/ionization time-of-flight/time-of-flight tandem mass spectrometry (MALDI-TOF-TOF MS). Plasma haptoglobin levels, and milk β-casein A2, αs1-casein variant and albumin, did not differ in cows after infusion of 0, 100, 200 and 300 g/day of LNA, but were increased after the cows received duodenal infusion of 400 g/day of LNA. Western blot analysis of haptoglobin expression in plasma confirmed the alterations in protein expression seen using MS. This study demonstrated that infusion of high doses of LNA by duodenal cannula can result in metabolic stress within the bovine intestine and in changes in milk composition.

Published

2013

70. Precision measurement of the branching fractions of J/ψ→π+π−π0 and ψ′→π+π−π0

Author

M. Ablikim, M.N. Achasov, D. Alberto, D.J. Ambrose, F.F. An, Q. An, Z.H. An, J.Z. Bai, R.B.F. Baldini Ferroli, Y. Ban, J. Becker, N. Berger, M.B. Bertani, J.M. Bian, E. Boger, O. Bondarenko, I. Boyko, R.A. Briere, V. Bytev, X. Cai, A.C. Calcaterra, G.F. Cao, J.F. Chang, G. Chelkov, G. Chen, H.S. Chen, J.C. Chen, M.L. Chen, S.J. Chen, Y. Chen, Y.B. Chen, H.P. Cheng, Y.P. Chu, D. Cronin-Hennessy, H.L. Dai, J.P. Dai, D. Dedovich, Z.Y. Deng, I. Denysenko, M. Destefanis, W.M. Ding, Y. Ding, L.Y. Dong, M.Y. Dong, S.X. Du, J. Fang, S.S. Fang, C.Q. Feng, C.D. Fu, J.L. Fu, Y. Gao, C. Geng, K. Goetzen, W.X. Gong, M. Greco, M.H. Gu, Y.T. Gu, Y.H. Guan, A.Q. Guo, L.B. Guo, Y.P. Guo, Y.L. Han, X.Q. Hao, F.A. Harris, K.L. He, M. He, Z.Y. He, Y.K. Heng, Z.L. Hou, H.M. Hu, J.F. Hu, T. Hu, B. Huang, G.M. Huang, J.S. Huang, X.T. Huang, Y.P. Huang, T. Hussain, C.S. Ji, Q. Ji, X.B. Ji, X.L. Ji, L.K. Jia, L.L. Jiang, X.S. Jiang, J.B. Jiao, Z. Jiao, D.P. Jin, S. Jin, F.F. Jing, N. Kalantar-Nayestanaki, M. Kavatsyuk, W. Kuehn, W. Lai, J.S. Lange, J.K.C. Leung, C.H. Li, Cheng Li, Cui Li, D.M. Li, F. Li, G. Li, H.B. Li, J.C. Li, K. Li, Lei Li, N.B. Li, Q.J. Li, S.L. Li, W.D. Li, W.G. Li, X.L. Li, X.N. Li, X.Q. Li, X.R. Li, Z.B. Li, H. Liang, Y.F. Liang, Y.T. Liang, G.R. Liao, X.T. Liao, B.J. Liu, C.L. Liu, C.X. Liu, C.Y. Liu, F.H. Liu, Fang Liu, Feng Liu, H. Liu, H.B. Liu, H.H. Liu, H.M. Liu, H.W. Liu, J.P. Liu, K. Liu, K.Y. Liu, Q. Liu, S.B. Liu, X. Liu, X.H. Liu, Y.B. Liu, Yong Liu, Z.A. Liu, Zhiqiang Liu, Zhiqing Liu, H. Loehner, G.R. Lu, H.J. Lu, J.G. Lu, Q.W. Lu, X.R. Lu, Y.P. Lu, C.L. Luo, M.X. Luo, T. Luo, X.L. Luo, M. Lv, C.L. Ma, F.C. Ma, H.L. Ma, Q.M. Ma, S. Ma, T. Ma, X.Y. Ma, M. Maggiora, Q.A. Malik, H. Mao, Y.J. Mao, Z.P. Mao, J.G. Messchendorp, J. Min, T.J. Min, R.E. Mitchell, X.H. Mo, N.Yu. Muchnoi, Y. Nefedov, I.B. Nikolaev, Z. Ning, S.L. Olsen, Q. Ouyang, S.P. Pacetti, J.W. Park, M. Pelizaeus, K. Peters, J.L. Ping, R.G. Ping, R. Poling, C.S.J. Pun, M. Qi, S. Qian, C.F. Qiao, X.S. Qin, Z.H. Qin, J.F. Qiu, K.H. Rashid, G. Rong, X.D. Ruan, A. Sarantsev, J. Schulze, M. Shao, C.P. Shen, X.Y. Shen, H.Y. Sheng, M.R. Shepherd, X.Y. Song, S. Spataro, B. Spruck, D.H. Sun, G.X. Sun, J.F. Sun, S.S. Sun, X.D. Sun, Y.J. Sun, Y.Z. Sun, Z.J. Sun, Z.T. Sun, C.J. Tang, X. Tang, E.H. Thorndike, H.L. Tian, D. Toth, M.U. Ulrich, G.S. Varner, B. Wang, B.Q. Wang, K. Wang, L.L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, Q. Wang, Q.J. Wang, S.G. Wang, X.F. Wang, X.L. Wang, Y.D. Wang, Y.F. Wang, Y.Q. Wang, Z. Wang, Z.G. Wang, Z.Y. Wang, D.H. Wei, Q.G. Wen, S.P. Wen, M.W. Werner, U. Wiedner, L.H. Wu, N. Wu, W. Wu, Z. Wu, L.G. Xia, Z.J. Xiao, Y.G. Xie, Q.L. Xiu, G.F. Xu, G.M. Xu, H. Xu, Q.J. Xu, X.P. Xu, Y. Xu, Z.R. Xu, F. Xue, Z. Xue, L. Yan, W.B. Yan, Y.H. Yan, H.X. Yang, T. Yang, Y. Yang, Y.X. Yang, H. Ye, M. Ye, M.H. Ye, B.X. Yu, C.X. Yu, S.P. Yu, C.Z. Yuan, W.L. Yuan, Y. Yuan, A.A. Zafar, A.Z. Zallo, Y. Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.H. Zhang, H.Y. Zhang, J. Zhang, J.Q. Zhang, J.W. Zhang, J.Y. Zhang, J.Z. Zhang, L. Zhang, S.H. Zhang, T.R. Zhang, X.J. Zhang, X.Y. Zhang, Y. Zhang, Y.H. Zhang, Y.S. Zhang, Z.P. Zhang, Z.Y. Zhang, G. Zhao, H.S. Zhao, Jingwei Zhao, Lei Zhao, Ling Zhao, M.G. Zhao, Q. Zhao, S.J. Zhao, T.C. Zhao, X.H. Zhao, Y.B. Zhao, Z.G. Zhao, A. Zhemchugov, B. Zheng, J.P. Zheng, Y.H. Zheng, Z.P. Zheng, B. Zhong, J. Zhong, L. Zhou, X.K. Zhou, X.R. Zhou, C. Zhu, K. Zhu, K.J. Zhu, S.H. Zhu, X.L. Zhu, X.W. Zhu, Y.S. Zhu, Z.A. Zhu, J. Zhuang, B.S. Zou, J.H. Zou, and J.X. Zuo

Subjects

Physics, Nuclear and High Energy Physics, Meson, 010308 nuclear & particles physics, Branching fraction, Electron–positron annihilation, Analytical chemistry, Dalitz plot, Branching (polymer chemistry), 01 natural sciences, Nuclear physics, 0103 physical sciences, Pi, Mass spectrum, 010306 general physics

Abstract

We study the decays of the J / ψ and ψ ′ mesons to π + π − π 0 using data samples at both resonances collected with the BES III detector in 2009. We measure the corresponding branching fractions with unprecedented precision and provide mass spectra and Dalitz plots. The branching fraction for J / ψ → π + π − π 0 is determined to be ( 2.137 ± 0.004 ( stat. ) − 0.056 + 0.058 ( syst. ) − 0.026 + 0.027 ( norm. ) ) × 10 − 2 , and the branching fraction for ψ ′ → π + π − π 0 is measured as ( 2.14 ± 0.03 ( stat. ) − 0.07 + 0.08 ( syst. ) − 0.08 + 0.09 ( norm. ) ) × 10 − 4 . The J / ψ decay is found to be dominated by an intermediate ρ ( 770 ) state, whereas the ψ ′ decay is dominated by di-pion masses around 2.2 GeV/ c 2 , leading to strikingly different Dalitz distributions.

Published

2012

71. Differential expression of peroxisome proliferator-activated receptor γ, fatty acid synthase, and hormone-sensitive lipase in fat-tailed and thin-tailed sheep breeds

Author

Chen Yahan, Xiaolong Wang, Y.X. Yang, Bibo Li, Xue Xu, and Xuan Wei

Subjects

Tail, medicine.medical_specialty, Adipose tissue, Peroxisome proliferator-activated receptor, Hormone-sensitive lipase, Gene Expression Regulation, Enzymologic, Internal medicine, Genetics, medicine, Animals, Differential expression, Molecular Biology, chemistry.chemical_classification, Regulation of gene expression, Sheep, biology, Lipid metabolism, General Medicine, Sterol Esterase, Lipid Metabolism, PPAR gamma, Fatty acid synthase, Endocrinology, Phenotype, chemistry, Wool, biology.protein, Fatty Acid Synthases

Abstract

Tail fat content affects meat quality, and it varies in different sheep breeds. Theoretically, lipid metabolism contributes to variation in tail fat content. Tail length, tail width, and tail girth were measured in live Tong sheep (with both short fat tail and long fat tail), Shaanbei fine wool sheep (long thin tail), Tan sheep (short fat tail), Kazakh sheep (hip fat tail), and Tibetan sheep (short thin tail). The expression levels of genes related to tail adipose tissue lipid metabolism were investigated, which included lipogenetic genes (PPARγ and FAS) and lipolytic gene (HSL). Differences were observed (P0.05) in PPARγ mRNA expression levels in the different breeds; FAS mRNA expression levels did not differ (P0.05) in Tong sheep with short fat tail, Tong sheep with long fat tail, Shaanbei fine wool sheep, and Tibetan sheep; HSL mRNA expression levels were not different (P0.05) in Tong sheep. PPARγ and HSL protein expression levels differed (P0.05) between the different breeds; FAS protein expression levels were different (P0.05) in Tong sheep with long fat tails, Tan sheep, Kazakh sheep, and Tibetan sheep, but did not differ (P0.05) in Tong sheep with short fat tails and Shaanbei fine wool sheep. These results provide useful information to further understand the function of PPARγ, FAS, and HSL in sheep tail lipid metabolism, which should be applicable to studies on the regulation of fat deposition and improvement of meat quality.

Published

2015

72. Facile synthesis of Bi2S3 network nanostructure

Author

Jianfeng Su, C. J. Tang, Y. S. Zhang, Y.X. Yang, Changqing Wang, Q.B. Hu, Chunhe Zang, and C. H. Zhao

Subjects

Emission band, Nanostructure, Chemistry, Nanostructured materials, Perpendicular, Nanowire, Hydrothermal synthesis, General Materials Science, Nanotechnology, General Chemistry, Condensed Matter Physics, Hydrothermal circulation

Abstract

Bi2S3 network nanostructure has been synthesized by a facile hydrothermal method. The networks are composed of cross-linked single crystalline Bi2S3 nanowires growth along [001] direction, and the nanowires form the network are almost perpendicular to each other. The influence factors and formation mechanism of the network were analyzed and discussed. A broad red emission band was observed and was attributed to the complex defects.

Published

2011

73. Genetic Variability in Cultured Stocks of Scleropages formosus in Mainland China Revealed by Microsatellite Markers

Author

X.J. Wang, Yinchang Hu, J.R. Luo, Y.X. Yang, H.M. Song, and X.D. Mu

Subjects

Mainland China, General Veterinary, biology, Microsatellite, Zoology, Genetic variability, biology.organism_classification, Agronomy and Crop Science, Scleropages formosus

Published

2011

74. A single vacancy diffusion near a Fe (110) surface: A molecular dynamics study

Author

Yanjie Jia, Changqing Wang, Y.X. Yang, and Y. S. Zhang

Subjects

Surface (mathematics), General Computer Science, Condensed matter physics, Chemistry, Diffusion, Many-body theory, General Physics and Astronomy, General Chemistry, Molecular physics, Standard enthalpy of formation, Computational Mathematics, Molecular dynamics, Mechanics of Materials, Vacancy defect, General Materials Science, Layer (electronics), Embedded atom model

Abstract

Both the formation energies, the intra-layer and inter-layer diffuse migration energies of a single vacancy in the first nine layers of the Fe (1 1 0) surface have been calculated by means of molecular dynamics in conjunction with the many-body potential of the embedded-atom method (EAM). The results show that the effect of the surface is only down to the fourth layer for the formation energy of a single vacancy. However, the surface presence affects the migration energy down to the seventh layer. It is easier for a vacancy in the first layer to form and to migrate than in the other layers and the bulk. For the inter-layer migration, a vacancy in each of the first six layers is favorable to migrate into the corresponding upper layer, especially for the first three layers.

Published

2010

75. Controlled synthesis of urchin-like Bi2S3 via hydrothermal method

Author

Zhengjun Zong, Chunhe Zang, C. J. Tang, Y. S. Zhang, Fengjian Su, Y.X. Yang, and Changqing Wang

Subjects

Materials science, Scanning electron microscope, Inorganic chemistry, Nanowire, General Chemistry, Condensed Matter Physics, symbols.namesake, Crystallography, Electron diffraction, Transmission electron microscopy, symbols, Hydrothermal synthesis, General Materials Science, Nanorod, Selected area diffraction, Raman spectroscopy

Abstract

The urchin-like Bi 2 S 3 nanostructures have been grown by a facile environmentally friendly hydrothermal method. X-ray diffraction (XRD) and Raman spectrum demonstrate that the obtained samples are composed of pure orthorhombic phase Bi 2 S 3 . Scanning electron microscopy (SEM) images and transmission electron microscopy (TEM) images reveal that it is produced as uniform urchin-like pattern with spherical symmetry. High-resolution (HR) TEM and selected-area electron diffraction (SAED) demonstrate that the nanowires which grow radially from the center of the urchin-like nanostructures toward all directions are single-crystalline and grow along the [001]. It is found that the reaction time, reaction temperature and thiourea (Tu) play key roles for the formation of urchin-like Bi 2 S 3 nanostructures. The formation mechanism is ascribed to self-assembly and the intrinsic splitting character of the Bi 2 S 3 structure. The urchin-like Bi 2 S 3 composed of porous nanorods, solid nanorods and nanowires could be found potential application in optical, catalysts and sensor devices.

Published

2010

76. Optical Properties of a ZnO/P Nanostructure Fabricated by a Chemical Vapor Deposition Method

Author

Zhengjun Zong, D. M. Zhang, Y.X. Yang, Y. S. Zhang, Chunhe Zang, S. J. Fang, C. H. Zhao, and C. J. Tang

Subjects

Photoluminescence, Nanostructure, Materials science, Scattering, Phonon, Analytical chemistry, Chemical vapor deposition, Substrate (electronics), Atmospheric temperature range, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, General Energy, Impurity, Physical and Theoretical Chemistry

Abstract

A diamond-shaped P-doped ZnO nanostructure was fabricated on a Si (100) substrate by a chemical vapor deposition method. The photoluminescence properties of the ZnO nanostructure were studied with a temperature range from 81 to 306 K. At 81 K, a series of transitions of donor-acceptor pairs and their phonon replicas were observed in the PL spectrum. These results revealed that shallow-donor and deep-acceptor impurity bands existed in the P-doped ZnO nanostructure. From 81 to 111 K, the abnormal UV emission intensity was observed. The multiphonon scattering spectra were attributed to the interaction of electrons and phonons.

Published

2009

77. Direct measurements of the cross sections for e+e−→hadrons|non-DD¯ in the range from 3.65 to 3.87 GeV and the branching fraction for ψ(3770)→non-DD¯

Author

M. Ablikim, J.Z. Bai, Y. Ban, X. Cai, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Y.B. Chen, Y.P. Chu, Y.S. Dai, L.Y. Diao, Z.Y. Deng, Q.F. Dong, S.X. Du, J. Fang, S.S. Fang, C.D. Fu, C.S. Gao, Y.N. Gao, S.D. Gu, Y.T. Gu, Y.N. Guo, K.L. He, M. He, Y.K. Heng, J. Hou, H.M. Hu, J.H. Hu, T. Hu, G.S. Huang, X.T. Huang, X.B. Ji, X.S. Jiang, X.Y. Jiang, J.B. Jiao, D.P. Jin, S. Jin, Y.F. Lai, G. Li, H.B. Li, J. Li, R.Y. Li, S.M. Li, W.D. Li, W.G. Li, X.L. Li, X.N. Li, X.Q. Li, Y.F. Liang, H.B. Liao, B.J. Liu, C.X. Liu, F. Liu, Fang Liu, H.H. Liu, H.M. Liu, J. Liu, J.B. Liu, J.P. Liu, Q. Liu, R.G. Liu, Z.A. Liu, Y.C. Lou, F. Lu, G.R. Lu, J.G. Lu, C.L. Luo, F.C. Ma, H.L. Ma, L.L. Ma, Q.M. Ma, Z.P. Mao, X.H. Mo, J. Nie, R.G. Ping, N.D. Qi, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, X.D. Ruan, L.Y. Shan, L. Shang, D.L. Shen, X.Y. Shen, H.Y. Sheng, H.S. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, X. Tang, G.L. Tong, D.Y. Wang, L. Wang, L.L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, W.F. Wang, Y.F. Wang, Z. Wang, Z.Y. Wang, Zheng Wang, C.L. Wei, D.H. Wei, Y. Weng, N. Wu, X.M. Xia, X.X. Xie, G.F. Xu, X.P. Xu, Y. Xu, M.L. Yan, H.X. Yang, Y.X. Yang, M.H. Ye, Y.X. Ye, G.W. Yu, C.Z. Yuan, Y. Yuan, S.L. Zang, Y. Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Q. Zhang, H.Y. Zhang, J.W. Zhang, J.Y. Zhang, S.H. Zhang, X.Y. Zhang, Yiyun Zhang, Z.X. Zhang, Z.P. Zhang, D.X. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, H.Q. Zheng, J.P. Zheng, Z.P. Zheng, L. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Z.A. Zhu, B.A. Zhuang, X.A. Zhuang, and B.S. Zou

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, Particle physics, Range (particle radiation), Branching fraction, Electron–positron annihilation, Hadron

Abstract

By tagging the largest energy of the assumed kaon in the final states of e + e − → hadrons , we measured the cross sections for e + e − → hadrons | non- D D ¯ in the range from 3.65 to 3.87 GeV. Analyzing these cross sections yields the branching fraction for the decay ψ ( 3770 ) → non- D D ¯ to be BF [ ψ ( 3770 ) → non- D D ¯ ] = ( 15.1 ± 5.6 ± 1.8 ) % , and the observed non- D D ¯ and D D ¯ cross sections to be σ had-non- D D ¯ obs = ( 1.08 ± 0.40 ± 0.15 ) nb and σ D D ¯ obs = ( 6.07 ± 0.40 ± 0.35 ) nb , respectively, at the center-of-mass energy E cm = 3.7724 GeV .

Published

2008

78. Production of σ in ψ(2S)→π+π−J/ψ

Author

M. Ablikim, J.Z. Bai, Y. Ban, X. Cai, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, Y.S. Dai, L.Y. Diao, Z.Y. Deng, Q.F. Dong, S.X. Du, J. Fang, S.S. Fang, C.D. Fu, C.S. Gao, Y.N. Gao, S.D. Gu, Y.T. Gu, Y.N. Guo, Y.Q. Guo, Z.J. Guo, F.A. Harris, K.L. He, M. He, Y.K. Heng, H.M. Hu, T. Hu, G.S. Huang, X.T. Huang, X.B. Ji, X.S. Jiang, X.Y. Jiang, J.B. Jiao, D.P. Jin, S. Jin, Yi Jin, Y.F. Lai, G. Li, H.B. Li, H.H. Li, J. Li, R.Y. Li, S.M. Li, W.D. Li, W.G. Li, X.L. Li, X.N. Li, X.Q. Li, Y.L. Li, Y.F. Liang, H.B. Liao, B.J. Liu, C.X. Liu, F. Liu, Fang Liu, H.H. Liu, H.M. Liu, J. Liu, J.B. Liu, J.P. Liu, Q. Liu, R.G. Liu, Z.A. Liu, Y.C. Lou, F. Lu, G.R. Lu, J.G. Lu, C.L. Luo, F.C. Ma, H.L. Ma, L.L. Ma, Q.M. Ma, X.B. Ma, Z.P. Mao, X.H. Mo, J. Nie, S.L. Olsen, H.P. Peng, R.G. Ping, N.D. Qi, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, C.P. Shen, D.L. Shen, X.Y. Shen, H.Y. Sheng, H.S. Sun, J.F. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, Z.Q. Tan, X. Tang, G.L. Tong, G.S. Varner, D.Y. Wang, L. Wang, L.L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, W.F. Wang, Y.F. Wang, Z. Wang, Z.Y. Wang, Zhe Wang, Zheng Wang, C.L. Wei, D.H. Wei, N. Wu, X.M. Xia, X.X. Xie, G.F. Xu, X.P. Xu, Y. Xu, M.L. Yan, H.X. Yang, Y.X. Yang, M.H. Ye, Y.X. Ye, Z.Y. Yi, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, S.L. Zang, Y. Zeng, Yu Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Q. Zhang, H.Y. Zhang, J.W. Zhang, J.Y. Zhang, S.H. Zhang, X.M. Zhang, X.Y. Zhang, Yiyun Zhang, Z.P. Zhang, D.X. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, Z.G. Zhao, H.Q. Zheng, J.P. Zheng, Z.P. Zheng, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Yingchun Zhu, Z.A. Zhu, B.A. Zhuang, X.A. Zhuang, and B.S. Zou

Subjects

Physics, Nuclear and High Energy Physics, Particle physics, Meson, Electron–positron annihilation, Mass spectrum, Pi, Sigma, Resonance, High Energy Physics::Experiment, Production (computer science), Helicity

Abstract

Using 14M psi(2S) events accumulated by BESII at the BEPC, a covariant helicity amplitude analysis is performed for psi(2S) -> pi(+)pi(-)J/psi, J/psi -> mu(+)mu(-). The pi(+)pi(-) mass spectrum, distinctly different from phase space, suggests or production in this process. Two different theoretical schemes are used in the global fit to the data. The results are consistent with the existence of the sigma. The sigma pole position is determined to be (552(-106)(+84) -i(232(-72)(+81)) MeV/c(2). (c) 2006 Elsevier B.V. All rights reserved.

Published

2007

79. Measurements of branching fractions for inclusive K¯0/K0 and K∗(892)∓ decays of neutral and charged D mesons

Author

M. Ablikim, J.Z. Bai, Y. Ban, J.G. Bian, X. Cai, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, Y.S. Dai, L.Y. Diao, Z.Y. Deng, Q.F. Dong, S.X. Du, J. Fang, S.S. Fang, C.D. Fu, C.S. Gao, Y.N. Gao, S.D. Gu, Y.T. Gu, Y.N. Guo, Y.Q. Guo, K.L. He, M. He, Y.K. Heng, H.M. Hu, T. Hu, G.S. Huang, X.T. Huang, X.B. Ji, X.S. Jiang, X.Y. Jiang, J.B. Jiao, D.P. Jin, S. Jin, Yi Jin, Y.F. Lai, G. Li, H.B. Li, H.H. Li, J. Li, R.Y. Li, S.M. Li, W.D. Li, W.G. Li, X.L. Li, X.N. Li, X.Q. Li, Y.L. Li, Y.F. Liang, H.B. Liao, B.J. Liu, C.X. Liu, F. Liu, Fang Liu, H.H. Liu, H.M. Liu, J. Liu, J.B. Liu, J.P. Liu, Q. Liu, R.G. Liu, Z.A. Liu, Y.C. Lou, F. Lu, G.R. Lu, J.G. Lu, C.L. Luo, F.C. Ma, H.L. Ma, L.L. Ma, Q.M. Ma, X.B. Ma, Z.P. Mao, X.H. Mo, J. Nie, H.P. Peng, R.G. Ping, N.D. Qi, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, C.P. Shen, D.L. Shen, X.Y. Shen, H.Y. Sheng, H.S. Sun, J.F. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, Z.Q. Tan, X. Tang, G.L. Tong, D.Y. Wang, L. Wang, L.L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, W.F. Wang, Y.F. Wang, Z. Wang, Z.Y. Wang, Zhe Wang, Zheng Wang, C.L. Wei, D.H. Wei, N. Wu, X.M. Xia, X.X. Xie, G.F. Xu, X.P. Xu, Y. Xu, M.L. Yan, H.X. Yang, Y.X. Yang, M.H. Ye, Y.X. Ye, Z.Y. Yi, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, S.L. Zang, Y. Zeng, Yu Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Q. Zhang, H.Y. Zhang, J.W. Zhang, J.Y. Zhang, S.H. Zhang, X.M. Zhang, X.Y. Zhang, Yiyun Zhang, Z.P. Zhang, D.X. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, Z.G. Zhao, H.Q. Zheng, J.P. Zheng, Z.P. Zheng, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Yingchun Zhu, Z.A. Zhu, B.A. Zhuang, X.A. Zhuang, and B.S. Zou

Subjects

Physics, Nuclear physics, Nuclear and High Energy Physics, Meson, Analytical chemistry, Branching (polymer chemistry)

Abstract

Using the data sample of about 33 pb(-1) collected at and around 3.773 GeV with the BES-II detector at the BEPC collider, we have studied inclusive (K) over bar (0)/K-0 and K*(892) -/+ decays of D-0 and D+ mesons. The branching fractions for the inclusive (K) over bar (0)/K-0 and K*(892)(-) decays are measured to be BF(D-0, (K) over bar (0)/(KX)-X-0) = (47.6 +/- 14.8 +/- 3.0)%, BF(D-0 -> (KX)-X-0) = (60.5 +/- 15.5 +/- 3.3)%, BF(D-0, K*X-) = (15.3 +/- 8.3 +/- 1.9)% and BF(D+ -> K*X-) = (5.7 +/- 5.2 +/- 0.7)%. The upper limits of the branching fractions for the inclusive K*(892)(+) decays are set to be BF(D-0 -> K*+X) K*X+) < 20.3% at 90% confidence level. (c) 2006 Elsevier B.V. All rights reserved.

Published

2006

80. Measurements of the cross sections for e+e−→hadrons at 3.650, 3.6648, 3.773 GeV and the branching fraction for ψ(3770)→non-DD¯

Author

N. Wu, Q. M. Zhu, H. Y. Zhang, Haiwen Liu, H. S. Chen, Z. Y. Yi, Xingzhu Cui, J. Y. Zhang, W. R. Zhao, M. Z. Wang, Yiyun Zhang, S. S. Sun, F. Liu, L. Y. Dong, H. S. Sun, Y. X. Ye, Yang Tian, Y. K. Heng, X. Q. Li, Xingtao Huang, Feng Shi, Haiping Peng, J. H. Liu, Y. F. Liang, D. P. Jin, D. X. Zhao, B. Y. Zhang, Xunchao Zhang, Hangxu Li, H. Qin, L. P. Zhou, Yin Xu, S. X. Du, M. L. Yan, F. Lu, H. L. Ma, Z. P. Mao, S. M. Li, Y. Q. Guo, Fan Yang, F. C. Ma, J. G. Lu, Y.X. Yang, Y. B. Chen, J. Nie, M. He, Zujian Wang, L. S. Wang, D. H. Zhang, M. G. Zhao, D. L. Shen, T. Hu, XZ（蔡翔舟） Cai, Y. S. Dai, Yi Jin, Y.N. Gao, Zheng Wang, X. B. Ma, Xuai Zhuang, Y. N. Guo, R. Y. Li, H. M. Hu, X. Y. Shen, J. W. Zhao, G. W. Yu, X. Shi, J. F. Qiu, X. S. Jiang, Zhenyu Zhang, C. S. Gao, Jinxing Zheng, Y. F. Lai, H. F. Chen, W. F. Wang, S. D. Gu, Lianyou Shan, Cunfeng Wei, Q. F. Dong, K. L. He, Jianbin Jiao, X. H. Mo, M. H. Ye, Ning Zhou, C. Z. Yuan, Y. Z. Sun, Zhe Wang, Yingchun Zhu, J. C. Chen, J. W. Zhang, X. Tang, Xuan Zhang, Qiyang Zhang, Y. T. Gu, C. X. Liu, J. Fang, Q. M. Ma, W. G. Li, P. Wang, D. Y. Wang, Bo Xin, D. H. Wei, Fang Liu, Z. J. Sun, J. P. Liu, J. G. Bian, S. L. Zang, W. D. Li, B. X. Zhang, Y. C. Zhu, Z. P. Zheng, H. X. Yang, G. F. Xu, S. Jin, H.Q. Zheng, B.S. Zou, Y. Yuan, Y. S. Zhu, Z. Y. Ren, P. P. Zhao, H. H. Liu, Z.Q. Zhang, J. C. Li, P. L. Wang, H.B. Liao, Xiru Huang, G. L. Tong, B. A. Zhuang, M. Ablikim, G. Rong, Jianwei Sun, X. M. Xia, Y. Zeng, H. B. Li, C. L. Luo, Houbing Lu, C. C. Zhang, Y. P. Chu, X. B. Ji, Y.L. Li, Shang Lunlin, G. Li, X.L. Li, C. D. Fu, Z. Y. Deng, Gongru Lu, S. P. Chi, K. J. Zhu, J. M. Yuan, Z. Y. Wang, Yu Zeng, X. X. Xie, Jin Chen, S. S. Fang, H. Y. Sheng, Z. Q. Tan, N. D. Qi, Z. Z. Du, L. L. Ma, Z. A. Liu, Y. Ban, J. Z. Bai, R. G. Liu, J. B. Liu, J. Yang, Yudan Wang, and Z. A. Zhu

Subjects

Physics, Nuclear and High Energy Physics, Branching fraction, Electron–positron annihilation, Hadron, Analytical chemistry

Abstract

Using the BES-II detector at the BEPC Collider, we measured the lowest order cross sections and the R values (R = sigma(0)(e+e--> hadrons)/sigma(0)(e+e-->mu+mu-)) for inclusive hadronic event production at the centre-of-mass energies of 3.650, 3.6648 and 3.773 GeV. The results lead to R-uds = 2.218 +/- 0.019 +/- 0.089 which is the average of these measured at 3.650 GeV and 3.6648 GeV, and R = 3.746 +/- 0.037 +/- 0.187 at root s = 3.773 GeV. We determined the lowest order cross section for psi (3770) production to be sigma(B)(psi)((3770)) = (9.323 +/- 0.253 +/- 0.801) nb at 3.773 GeV, the branching fractions for psi (3770) decays to be BF(psi (3770) -> D-0(D) over bar (0)) = (49.5 +/- 1.3 +/- 3.8)%, BF(psi (3770) -> D+D-) = (35.7 +/- 1.1 +/- 3.4)% and BF(psi (3770) -> D (D) over bar) = (85.5 +/- 1.7 +/- 5.8)%, which result in the total non-D (D) over bar branching fraction of psi(3770) decay to be BF(psi (3770) -> non-D (D) over bar) = (14.5 +/- 1.7 +/- 5.8)%. (c) 2006 Elsevier B.V. All rights reserved.

Published

2006

81. Evidence for κ meson production in J/ψ→K¯∗(892)0K+π− process

Author

Kunio Takamatsu, Jin Chen, S. S. Fang, F. C. Ma, Zheng Wang, H. B. Li, X. X. Xie, Yingchun Zhu, C. L. Luo, Zhenyu Zhang, J. G. Lu, Houbing Lu, X. Q. Li, I. Yamauchi, R. Y. Li, J. F. Qiu, C. C. Zhang, H. L. Ma, S. M. Li, Fan Yang, T. Hu, Shin-ichi Kurokawa, X. M. Xia, Z. Z. Du, Gongru Lu, XZ（蔡翔舟） Cai, Y. T. Gu, Bo Xin, L. P. Zhou, Z.Q. Zhang, Q. M. Ma, Yudan Wang, Z. Y. Yi, J. C. Chen, Z. P. Mao, W. D. Li, J. P. Liu, Cunfeng Wei, S. P. Chi, Y. Yuan, Y. S. Zhu, Z. Y. Wang, Muneyuki Ishida, Q. F. Dong, X. Tang, Xuan Zhang, K. Ukai, Ning Zhou, Xingtao Huang, Lianyou Shan, H. S. Chen, Y. Z. Sun, H. H. Liu, J. C. Li, Toshihiko Komada, D. H. Wei, Z. A. Zhu, Y. C. Zhu, H. Qin, T. Matsuda, J. Fang, B. X. Zhang, Xingzhu Cui, J. G. Bian, Zujian Wang, P. L. Wang, J. W. Zhang, H. X. Yang, J. H. Liu, L. L. Ma, Xunchao Zhang, Z. P. Zheng, J. W. Zhao, Z. A. Liu, G. W. Yu, S. L. Zang, M. He, J. Nie, X. H. Mo, W. R. Zhao, K. J. Zhu, J. M. Yuan, F. A. Harris, L. S. Wang, H. M. Hu, F. Liu, D. L. Shen, Feng Shi, M. H. Ye, Y. Ban, Xiru Huang, S. S. Sun, G. L. Tong, B. A. Zhuang, Y. Zeng, M. G. Zhao, C. X. Liu, Y.L. Li, Jianwei Sun, F. Lu, Yu Zeng, Y. S. Dai, Z.J. Guo, J. Z. Bai, H. Y. Zhang, Haiwen Liu, C. S. Gao, Jinxing Zheng, Z. G. Zhao, G. S. Huang, H.B. Liao, X. B. Ma, Xuai Zhuang, X. Y. Shen, Shang Lunlin, J. Y. Zhang, Fang Liu, K. Yamada, P. P. Zhao, G. F. Xu, Z. J. Sun, Y. N. Guo, S. Jin, Shin Ishida, Tsuneaki Tsuru, Q. M. Zhu, H. Y. Sheng, Z. Y. Ren, Y. K. Heng, Z. Q. Tan, Zhe Wang, Qiyang Zhang, G. Li, Yang Tian, K. L. He, P. Wang, M. Z. Wang, Y. F. Liang, N. D. Qi, M. Ablikim, D. X. Zhao, S. X. Du, D. P. Jin, B. Y. Zhang, G. Rong, Hangxu Li, M. L. Yan, X.L. Li, W. G. Li, H. S. Sun, C. D. Fu, Haiping Peng, Yin Xu, D. H. Zhang, D. Y. Wang, X. Shi, Yi Jin, Y.N. Gao, Z. Y. Deng, J. Yang, H.Q. Zheng, R. G. Liu, J. B. Liu, Y. P. Chu, X. B. Ji, N. Wu, Yiyun Zhang, Y. X. Ye, Y. Q. Guo, X. S. Jiang, Y.X. Yang, Y. B. Chen, Y. F. Lai, H. F. Chen, W. F. Wang, Jianbin Jiao, and S. D. Gu

Subjects

Physics, Nuclear physics, Nuclear and High Energy Physics, Meson production, Electron–positron annihilation, Partial wave analysis, Phase space, Scalar (mathematics), Analytical chemistry, Invariant mass, Low Mass

Abstract

Based on 58 million BESII J / ψ events, the K ¯ ∗ ( 892 ) 0 K + π − channel in K + K − π + π − is studied. A clear low mass enhancement in the invariant mass spectrum of K + π − is observed. The low mass enhancement does not come from background of other J / ψ decay channels, nor from phase space. Two independent partial wave analyses have been performed. Both analyses favor that the low mass enhancement is the κ , an iso-spinor scalar resonant state. The average mass and width of the κ in the two analyses are 878 ± 23 −55 +64 MeV / c 2 and 499 ± 52 −87 +55 MeV / c 2 , respectively, corresponding to a pole at ( 841 ± 30 −73 +81 ) − i ( 309 ± 45 −72 +48 ) MeV / c 2 .

Published

2006

82. Measurement of the cross section for e+e−→pp¯ at center-of-mass energies from 2.0 to 3.07 GeV

Author

H. Y. Zhang, Haiwen Liu, G. S. Huang, L. P. Zhou, Z. P. Mao, J. Y. Zhang, X. Q. Li, Xingzhu Cui, Yiyun Zhang, Z. G. Zhao, Gongru Lu, Y. X. Ye, Y. K. Heng, H. Qin, Jin Chen, Yu Zeng, S. S. Sun, S. P. Chi, Fang Liu, Z. J. Sun, H. S. Chen, H. Y. Sheng, Z. Q. Tan, F. C. Ma, Feng Shi, S. S. Fang, N. D. Qi, S. L. Zang, K. J. Zhu, J. M. Yuan, Q. M. Zhu, Z. Z. Du, H. L. Ma, S. M. Li, Xunchao Zhang, S.L. Olsen, Y.L. Li, Y. Q. Guo, H. M. Hu, Z.J. Guo, Y.X. Yang, X. S. Jiang, F. Yang, Shang Lunlin, W. G. Li, J. F. Qiu, M. Z. Wang, Y. B. Chen, L. S. Wang, S. D. Gu, W. R. Zhao, D. Y. Wang, M. G. Zhao, G. Li, F. Liu, H. S. Sun, X.L. Li, H.B. Liao, Qiyang Zhang, Y. F. Lai, L. L. Ma, H. B. Li, Z. A. Liu, R. Y. Li, Yingchun Zhu, J. W. Zhao, X. B. Ma, Xuai Zhuang, C. D. Fu, W. F. Wang, Haiping Peng, P. Wang, G. W. Yu, K. L. He, C. L. Luo, Y. Ban, Z. Y. Deng, C. C. Zhang, X. Y. Shen, Cunfeng Wei, X. Shi, Zheng Wang, Q. F. Dong, Ning Zhou, Z. Y. Yi, J. W. Zhang, G. S. Varner, Zhenyu Zhang, J. Z. Bai, D. X. Zhao, B. Y. Zhang, Hangxu Li, Jianbin Jiao, J. P. Liu, J. G. Bian, X. Tang, Xuan Zhang, Y. Z. Sun, Y. C. Zhu, F. Lu, Z. Y. Wang, H. H. Liu, J. C. Li, Yudan Wang, G. F. Xu, J. C. Chen, J. Yang, P. L. Wang, J. H. Liu, H.Q. Zheng, Y. P. Chu, X. B. Ji, B. X. Zhang, J. Fang, S. Jin, Z. P. Zheng, J. Nie, Bo Xin, Yin Xu, N. Wu, F. A. Harris, Y.R. Tian, Y. S. Dai, Y. F. Liang, Xiru Huang, D. P. Jin, W. D. Li, C. S. Gao, H. X. Yang, Jinxing Zheng, Yi Jin, G. L. Tong, Y. Zeng, B. A. Zhuang, Y.N. Gao, R. G. Liu, D. H. Zhang, J. B. Liu, Jianwei Sun, Hao-Ze Chen, Z. Y. Ren, P. P. Zhao, C. Z. Yuan, Zhe Wang, Q. M. Ma, M. Ablikim, G. Rong, X. X. Xie, B.S. Zou, H. J. Lu, J. G. Lu, Y. Yuan, Y. S. Zhu, Xingtao Huang, T. Hu, XZ（蔡翔舟） Cai, Lianyou Shan, M. He, D. L. Shen, C. X. Liu, Z.Q. Zhang, X. M. Xia, S. X. Du, M. L. Yan, Z. A. Zhu, Y. N. Guo, X. H. Mo, M. H. Ye, L. Y. Dong, Zujian Wang, Y. T. Gu, and D. H. Wei

Subjects

Quantum chromodynamics, Physics, Nuclear and High Energy Physics, Particle physics, Cross section (physics), Proton, 010308 nuclear & particles physics, Electron–positron annihilation, 0103 physical sciences, Center of mass, 010306 general physics, 01 natural sciences, Bar (unit)

Abstract

Cross sections for e(+)e(-) -> p (p) over bar have been measured at 10 center-of-mass energies from 2.0 to 3.07 GeV by the BESII experiment at the BEPC, and proton electromagnetic form factors in the time-like region have been determined. (c) 2005 Elsevier B.V. All rights reserved.

Published

2005

83. First observation of χcJ→ωω decays

Author

M. Ablikim, J.Z. Bai, Y. Ban, J.G. Bian, X. Cai, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, Y.S. Dai, Z.Y. Deng, L.Y. Dong, Q.F. Dong, S.X. Du, Z.Z. Du, J. Fang, S.S. Fang, C.D. Fu, C.S. Gao, Y.N. Gao, S.D. Gu, Y.T. Gu, Y.N. Guo, Y.Q. Guo, Z.J. Guo, F.A. Harris, K.L. He, M. He, Y.K. Heng, H.M. Hu, T. Hu, G.S. Huang, X.P. Huang, X.T. Huang, X.B. Ji, X.S. Jiang, J.B. Jiao, D.P. Jin, S. Jin, Yi Jin, Y.F. Lai, G. Li, H.B. Li, H.H. Li, J. Li, R.Y. Li, S.M. Li, W.D. Li, W.G. Li, X.L. Li, X.Q. Li, Y.L. Li, Y.F. Liang, H.B. Liao, C.X. Liu, F. Liu, Fang Liu, H.H. Liu, H.M. Liu, J. Liu, J.B. Liu, J.P. Liu, R.G. Liu, Z.A. Liu, F. Lu, G.R. Lu, H.J. Lu, J.G. Lu, C.L. Luo, F.C. Ma, H.L. Ma, L.L. Ma, Q.M. Ma, X.B. Ma, Z.P. Mao, X.H. Mo, J. Nie, S.L. Olsen, H.P. Peng, N.D. Qi, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, D.L. Shen, X.Y. Shen, H.Y. Sheng, F. Shi, X. Shi, H.S. Sun, J.F. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, Z.Q. Tan, X. Tang, Y.R. Tian, G.L. Tong, G.S. Varner, D.Y. Wang, L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, W.F. Wang, Y.F. Wang, Z. Wang, Z.Y. Wang, Zhe Wang, Zheng Wang, C.L. Wei, D.H. Wei, N. Wu, X.M. Xia, X.X. Xie, B. Xin, G.F. Xu, Y. Xu, M.L. Yan, F. Yang, H.X. Yang, J. Yang, Y.X. Yang, M.H. Ye, Y.X. Ye, Z.Y. Yi, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, S.L. Zang, Y. Zeng, Yu Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Y. Zhang, J.W. Zhang, J.Y. Zhang, Q.J. Zhang, X.M. Zhang, X.Y. Zhang, Yiyun Zhang, Z.P. Zhang, Z.Q. Zhang, D.X. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, H.Q. Zheng, Z.G. Zhao, J.P. Zheng, Z.P. Zheng, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Yingchun Zhu, Z.A. Zhu, B.A. Zhuang, X.A. Zhuang, and B.S. Zou

Subjects

Physics, Nuclear and High Energy Physics, Particle physics, Omega

Abstract

Decays of $\chi_{c0,2}\ar\ww$ are observed for the first time using a sample of $14.0\times 10^6$ $\psi(2S)$ events collected with the BESII detector. The branching ratios are determined to be ${\cal B}(\chi_{c0}\ar \ww)=(2.29\pm 0.58\pm 0.41)\times 10^{-3}$ and ${\cal B}(\chi_{c2}\ar\ww)=(1.77\pm 0.47\pm 0.36)\times 10^{-3}$, where the first errors are statistical and the second systematic. The significances of the two signals are $4.4\sigma$ and $4.7\sigma$, respectively.

Published

2005

84. Measurements of Cabibbo-suppressed hadronic decay fractions of charmed D0 and D+ mesons

Author

M. Ablikim, J.Z. Bai, Y. Ban, J.G. Bian, X. Cai, J.F. Chang, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Jun Chen, M.L. Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, H.L. Dai, Y.S. Dai, Z.Y. Deng, L.Y. Dong, Q.F. Dong, S.X. Du, Z.Z. Du, J. Fang, S.S. Fang, C.D. Fu, H.Y. Fu, C.S. Gao, Y.N. Gao, M.Y. Gong, W.X. Gong, S.D. Gu, Y.N. Guo, Y.Q. Guo, K.L. He, M. He, X. He, Y.K. Heng, H.M. Hu, T. Hu, X.P. Huang, X.T. Huang, X.B. Ji, C.H. Jiang, X.S. Jiang, D.P. Jin, S. Jin, Y. Jin, Yi Jin, Y.F. Lai, F. Li, G. Li, H.H. Li, J. Li, J.C. Li, Q.J. Li, R.Y. Li, S.M. Li, W.D. Li, W.G. Li, X.L. Li, X.Q. Li, Y.L. Li, Y.F. Liang, H.B. Liao, C.X. Liu, F. Liu, Fang Liu, H.H. Liu, H.M. Liu, J. Liu, J.B. Liu, J.P. Liu, R.G. Liu, Z.A. Liu, Z.X. Liu, F. Lu, G.R. Lu, H.J. Lu, J.G. Lu, C.L. Luo, L.X. Luo, X.L. Luo, F.C. Ma, H.L. Ma, J.M. Ma, L.L. Ma, Q.M. Ma, X.B. Ma, X.Y. Ma, Z.P. Mao, X.H. Mo, J. Nie, Z.D. Nie, H.P. Peng, N.D. Qi, C.D. Qian, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, D.L. Shen, X.Y. Shen, H.Y. Sheng, F. Shi, X. Shi, H.S. Sun, J.F. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, X. Tang, N. Tao, Y.R. Tian, G.L. Tong, D.Y. Wang, J.Z. Wang, K. Wang, L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, S.Z. Wang, W.F. Wang, Y.F. Wang, Z. Wang, Z.Y. Wang, Zhe Wang, Zheng Wang, C.L. Wei, D.H. Wei, N. Wu, Y.M. Wu, X.M. Xia, X.X. Xie, B. Xin, G.F. Xu, H. Xu, S.T. Xue, M.L. Yan, F. Yang, H.X. Yang, J. Yang, Y.X. Yang, M. Ye, M.H. Ye, Y.X. Ye, L.H. Yi, Z.Y. Yi, C.S. Yu, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, S.L. Zang, Y. Zeng, Yu Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Y. Zhang, J. Zhang, J.W. Zhang, J.Y. Zhang, Q.J. Zhang, S.Q. Zhang, X.M. Zhang, X.Y. Zhang, Y.Y. Zhang, Yiyun Zhang, Z.P. Zhang, Z.Q. Zhang, D.X. Zhao, J.B. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, X.J. Zhao, Y.B. Zhao, H.Q. Zheng, J.P. Zheng, L.S. Zheng, Z.P. Zheng, X.C. Zhong, B.Q. Zhou, G.M. Zhou, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Yingchun Zhu, Z.A. Zhu, B.A. Zhuang, X.A. Zhuang, and B.S. Zou

Subjects

Hadronic decay, Physics, Nuclear and High Energy Physics, Particle physics, Meson, Branching fraction, Electron–positron annihilation, Hadron, law.invention, Nuclear physics, Positron, law, Pi, Collider

Abstract

Using data collected with the BESII detector at Beijing Electron-Positron Collider, the measurements of relative branchin- fractions for seven Cabibbo-suppressed hadronic weak decays D-0 -> K-K+, pi-pi(+), pi(-)pi(+)pi(-) and pi-pi(+)pi(-), D-divided by -> (K) over bar K-0(divided by), K-K+pi(+) and pi(-),pi(+pi+) are presented. (c) 2005 Elsevier B.V. All rights reserved.

Published

2005

85. Partial wave analysis of ψ′→π+π−π0 at BESII

Author

M. Ablikim, J.Z. Bai, Y. Ban, J.G. Bian, X. Cai, J.F. Chang, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Jun Chen, M.L. Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, H.L. Dai, Y.S. Dai, Z.Y. Deng, L.Y. Dong, S.X. Du, Z.Z. Du, J. Fang, S.S. Fang, C.D. Fu, H.Y. Fu, C.S. Gao, Y.N. Gao, M.Y. Gong, W.X. Gong, S.D. Gu, Y.N. Guo, Y.Q. Guo, Z.J. Guo, F.A. Harris, K.L. He, M. He, X. He, Y.K. Heng, H.M. Hu, T. Hu, G.S. Huang, L. Huang, X.P. Huang, X.B. Ji, Q.Y. Jia, C.H. Jiang, X.S. Jiang, D.P. Jin, S. Jin, Y. Jin, Y.F. Lai, F. Li, G. Li, H.H. Li, J. Li, J.C. Li, Q.J. Li, R.B. Li, R.Y. Li, S.M. Li, W.G. Li, X.L. Li, X.Q. Li, X.S. Li, Y.F. Liang, H.B. Liao, C.X. Liu, F. Liu, Fang Liu, H.M. Liu, J.B. Liu, J.P. Liu, R.G. Liu, Z.A. Liu, Z.X. Liu, F. Lu, G.R. Lu, J.G. Lu, C.L. Luo, X.L. Luo, F.C. Ma, J.M. Ma, L.L. Ma, Q.M. Ma, X.Y. Ma, Z.P. Mao, X.H. Mo, J. Nie, Z.D. Nie, S.L. Olsen, H.P. Peng, N.D. Qi, C.D. Qian, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, D.L. Shen, X.Y. Shen, H.Y. Sheng, F. Shi, X. Shi, H.S. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, X. Tang, N. Tao, Y.R. Tian, G.L. Tong, G.S. Varner, D.Y. Wang, J.Z. Wang, K. Wang, L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, S.Z. Wang, W.F. Wang, Y.F. Wang, Zhe Wang, Z. Wang, Zheng Wang, Z.Y. Wang, C.L. Wei, D.H. Wei, N. Wu, Y.M. Wu, X.M. Xia, X.X. Xie, B. Xin, G.F. Xu, H. Xu, Y. Xu, S.T. Xue, M.L. Yan, F. Yang, H.X. Yang, J. Yang, S.D. Yang, Y.X. Yang, M. Ye, M.H. Ye, Y.X. Ye, L.H. Yi, Z.Y. Yi, C.S. Yu, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, Q. Yue, S.L. Zang, Yu Zeng, Y. Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Y. Zhang, J. Zhang, J.Y. Zhang, J.W. Zhang, L.S. Zhang, Q.J. Zhang, S.Q. Zhang, X.M. Zhang, X.Y. Zhang, Y.J. Zhang, Y.Y. Zhang, Yiyun Zhang, Z.P. Zhang, Z.Q. Zhang, D.X. Zhao, J.B. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, X.J. Zhao, Y.B. Zhao, Z.G. Zhao, H.Q. Zheng, J.P. Zheng, L.S. Zheng, Z.P. Zheng, X.C. Zhong, B.Q. Zhou, G.M. Zhou, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Yingchun Zhu, Z.A. Zhu, B.A. Zhuang, and B.S. Zou

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, Amplitude, Branching fraction, Partial wave analysis, Electron–positron annihilation, Hadron, Pi, Analytical chemistry, Resonance, Helicity

Abstract

The decay psi' + pi(+)pi(-)pi(0) is analyzed using a sample of 14 million psi' events taken with the BESII detector at the BEPC, and the branching fraction is measured to be B(psi' -> pi(+)pi(-)pi(0)) = (18.1 +/- 1.8 +/- 1.9) x 10(-5). A partial wave analysis is carried out using the helicity amplitude method. psi' -> rho(770)pi is observed, and the branching fraction is measured to be B(psi' -> rho(770)pi) = (5.1 +/- 0.7 +/- 1.1) x 10(-5), where the first error is statistical and the second one is systematic. A high mass enhancement with mass around 2.15 GeV/c(2) is also observed. Attributing this enhancement to the p(2150) resonance, the branching fraction is measured to be B(psi' -> rho(2150)pi -> pi(+)pi(-)pi(0)) = (19.4 +/- 2.5(-3.4)(+11.5)) x 10(-5). The results will help in the understanding of the longstanding "rho pi puzzle" between J/psi and psi' hadronic decays. (c) 2005 Elsevier B.V. All rights reserved.

Published

2005

86. Measurements of J/ψ decays into 2(π+π−)η and 3(π+π−)η

Author

C. L. Luo, Houbing Lu, Nongjian Tao, C. C. Zhang, J. W. Zhao, W. R. Zhao, F. Liu, G. W. Yu, Xingzhu Cui, S. Z. Wang, X. H. Mo, L. S. Wang, M. H. Ye, H. X. Yang, H.S. Xu, Qiyang Zhang, S. S. Sun, G. F. Xu, Z. G. Zhao, Fang Liu, Z. J. Sun, Feng Shi, S. Jin, L. X. Luo, Y.R. Tian, J. G. Bian, H. H. Liu, P. Wang, J. C. Li, J. F. Chang, N. Wu, S. Q. Zhang, Jin Chen, X. Q. Li, H. M. Hu, L. Y. Dong, M. L. Chen, Z. Y. Ren, Y. Zeng, Guangzhao Zhou, Y. Z. Sun, S. S. Fang, Xunchao Zhang, Bo Xin, H. Y. Sheng, R. G. Liu, Q. M. Ma, J. B. Liu, Yiyun Zhang, H. Qin, S. D. Gu, H. S. Chen, W. D. Li, Z. Y. Yi, N. D. Qi, Yingchun Zhu, Gongru Lu, F. Lu, Xingtao Huang, J. B. Zhao, Y. X. Ye, Y. M. Wu, L. L. Ma, Jun-Bing Ma, Z. A. Liu, W. G. Li, G. S. Varner, J. G. Lu, X. S. Jiang, Q. J. Li, X. Y. Ma, W. X. Gong, X. Y. Shen, Yu Zeng, B. X. Zhang, Y. Ban, Y. Yuan, Y. S. Zhu, D. H. Wei, Jun Chen, P. P. Zhao, S. P. Chi, Z.J. Guo, X. Shi, T. Hu, XZ（蔡翔舟） Cai, M. He, D. L. Shen, Yudan Wang, M. G. Zhao, S. T. Xue, J. Z. Bai, D. Y. Wang, C. X. Liu, C. Z. Yuan, Z. Z. Du, Zhe Wang, R. Y. Li, Z. A. Zhu, L. H. Yi, H. Y. Zhang, D. X. Zhao, B. Y. Zhang, Hangxu Li, Haiwen Liu, Jiemin Li, M. Ablikim, G. Rong, Z. X. Liu, K. J. Zhu, Cunfeng Wei, H. L. Ma, Lianyou Shan, S. M. Li, G. S. Huang, Q. F. Dong, Ning Zhou, X. X. Xie, J. M. Yuan, J. Y. Zhang, X. C. Zhong, J. W. Zhang, Bing Zhou, Z. Y. Wang, J. Yang, K. L. He, Y.L. Li, Y. K. Heng, Y. Y. Zhang, Zheng Wang, X. M. Xia, Zhenyu Zhang, X. L. Luo, Zujian Wang, Z. P. Zheng, Shang Lunlin, Yi Jin, Y.N. Gao, J. C. Chen, H. Y. Fu, Jiang Changhui, J. Fang, C. D. Qian, G. Li, L. S. Zheng, Y. Jin, Xiru Huang, X.L. Li, G. L. Tong, B. A. Zhuang, Y. Q. Guo, C. D. Fu, Jianwei Sun, Y.X. Yang, Y. B. Chen, Z. Y. Deng, B.S. Zou, Y. F. Lai, H. F. Chen, W. F. Wang, Z.Q. Zhang, Y. B. Zhao, X. J. Zhao, X. Tang, Xuan Zhang, Y. P. Chu, X. B. Ji, F. C. Ma, J. F. Qiu, Y. C. Zhu, M. Y. Gong, P. L. Wang, F. A. Harris, Juan Zhang, Y. N. Guo, S. X. Du, M. L. Yan, X. H. He, H.Q. Zheng, Q. M. Zhu, Kelin Wang, Z. D. Nie, M. Z. Wang, J. Z. Wang, Y. F. Liang, D. P. Jin, D. H. Zhang, C. S. Yu, H. S. Sun, Haiping Peng, L. P. Zhou, Z. P. Mao, F. Y. Li, J. P. Liu, S. L. Zang, H. L. Dai, S.L. Olsen, J. H. Liu, H.B. Liao, X. B. Ma, Xuai Zhuang, J. Nie, Y. S. Dai, C. S. Gao, Jinxing Zheng, and F. Yang

Subjects

Physics, Nuclear and High Energy Physics, Nuclear magnetic resonance, Branching fraction, Pi, Analytical chemistry, Branching (polymer chemistry)

Abstract

Based on a sample of 5.8 x 10(7) J/psi events taken with the BESII detector, the branching fractions of J/psi -> 2(pi(+)pi(-))eta and J/psi -> 3(pi(+)pi(-))eta are measured for the first time to be (2.26 +/- 0.08 +/- 0.27) x 10(-3) and (7.24 +/- 0.96 +/- 1.11) x 10(-4), respectively. (c) 2005 Elsevier B.V. All rights reserved.

Published

2005

87. Study of micro-phase separation of two polystyrene-based copolymer mixture using the combination of PALS and FT-IR

Author

Y.X. Yang, Yan-Jun Huang, Yuanfu Hsia, H.B. Huang, Xiqun Jiang, and Zhong-Ying Jiang

Subjects

Nuclear and High Energy Physics, Materials science, Intermolecular force, technology, industry, and agriculture, SMA, Miscibility, chemistry.chemical_compound, Differential scanning calorimetry, chemistry, Chemical engineering, Polymer chemistry, Copolymer, Polystyrene, Polymer blend, Fourier transform infrared spectroscopy, Instrumentation

Abstract

Positron annihilation lifetime (PAL) spectroscopy, Fourier transform infrared (FT-IR) and differential scanning calorimetry (DSC) have been applied to study the micro-phase separation in the blends of poly(styrene-co-methylmethacrylate) (SMMA) copolymer and poly(styrene-co-maleic anhydride) (SMA) copolymer. The DSC results indicate that the SMA/SMMA blends are miscible and weak intermolecular interactions exist between SMA and SMMA. The strength of intermolecular interactions to some degree exhibits somewhat non-monotonic variation with increasing of SMA component in the blends. The results of PAL measurement present the blend containing 20 wt% SMA is phase-separated in molecular level, which is interpreted by the results of FT-IR analysis. It was concluded that it is helpful to study the miscibility of polymer blends in molecular level by means of PAL method, accompanied with the requisite measurement of DSC and FT-IR.

Published

2005

88. Resonances in and

Author

M. Ablikim, J.Z. Bai, Y. Ban, J.G. Bian, D.V. Bugg, X. Cai, J.F. Chang, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Jun Chen, M.L. Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, H.L. Dai, Y.S. Dai, Z.Y. Deng, L.Y. Dong, Q.F. Dong, S.X. Du, Z.Z. Du, J. Fang, S.S. Fang, C.D. Fu, H.Y. Fu, C.S. Gao, Y.N. Gao, M.Y. Gong, W.X. Gong, S.D. Gu, Y.N. Guo, Y.Q. Guo, Z.J. Guo, F.A. Harris, K.L. He, M. He, X. He, Y.K. Heng, H.M. Hu, T. Hu, G.S. Huang, X.P. Huang, X.T. Huang, X.B. Ji, C.H. Jiang, X.S. Jiang, D.P. Jin, S. Jin, Y. Jin, Yi Jin, Y.F. Lai, F. Li, G. Li, H.H. Li, J. Li, J.C. Li, Q.J. Li, R.Y. Li, S.M. Li, W.D. Li, W.G. Li, X.L. Li, X.Q. Li, Y.L. Li, Y.F. Liang, H.B. Liao, C.X. Liu, F. Liu, Fang Liu, H.H. Liu, H.M. Liu, J. Liu, J.B. Liu, J.P. Liu, R.G. Liu, Z.A. Liu, Z.X. Liu, F. Lu, G.R. Lu, H.J. Lu, J.G. Lu, C.L. Luo, L.X. Luo, X.L. Luo, F.C. Ma, H.L. Ma, J.M. Ma, L.L. Ma, Q.M. Ma, X.B. Ma, X.Y. Ma, Z.P. Mao, X.H. Mo, J. Nie, Z.D. Nie, S.L. Olsen, H.P. Peng, N.D. Qi, C.D. Qian, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, D.L. Shen, X.Y. Shen, H.Y. Sheng, F. Shi, X. Shi, H.S. Sun, J.F. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, X. Tang, N. Tao, Y.R. Tian, G.L. Tong, G.S. Varner, D.Y. Wang, J.Z. Wang, K. Wang, L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, S.Z. Wang, W.F. Wang, Y.F. Wang, Z. Wang, Z.Y. Wang, Zhe Wang, Zheng Wang, C.L. Wei, D.H. Wei, Y.M. Wu, X.M. Xia, X.X. Xie, B. Xin, G.F. Xu, H. Xu, S.T. Xue, M.L. Yan, F. Yang, H.X. Yang, J. Yang, Y.X. Yang, M. Ye, M.H. Ye, Y.X. Ye, L.H. Yi, Z.Y. Yi, C.S. Yu, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, S.L. Zang, Y. Zeng, Yu Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Y. Zhang, J. Zhang, J.W. Zhang, J.Y. Zhang, Q.J. Zhang, S.Q. Zhang, X.M. Zhang, X.Y. Zhang, Y.Y. Zhang, Yiyun Zhang, Z.P. Zhang, Z.Q. Zhang, D.X. Zhao, J.B. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, X.J. Zhao, Y.B. Zhao, Z.G. Zhao, H.Q. Zheng, J.P. Zheng, L.S. Zheng, Z.P. Zheng, X.C. Zhong, B.Q. Zhou, G.M. Zhou, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Yingchun Zhu, Z.A. Zhu, B.A. Zhuang, X.A. Zhuang, and B.S. Zou

Subjects

Physics, Nuclear physics, Nuclear and High Energy Physics, Meson, Electron–positron annihilation, Partial wave analysis, Mass spectrum, Analytical chemistry, Dalitz plot, State (functional analysis), Scalar meson, Bar (unit)

Abstract

A partial wave analysis is presented of J/psi --> phipi(+)pi(-) and phiK(+)K(-) from a sample of 58M J/psi events in the BES II detector. The f(0)(980) is observed clearly in both sets of data, and parameters of the Flatte formula are determined accurately: M = 965 +/- 8(stat) +/- 6(syst) MeV/c(2), g(1) = 165 +/- 10 +/- 15 MeV/c(2), g(2)/g(1) = 4.21 +/- 0.25 +/- 0.21. The phipipi data also exhibit a strong pipi peak centred at M = 1335 MeV/c(2). It may be fitted with f(2)(1270) and a dominant 0(+) signal made from f(0)(1370) interfering with a smaller f(0)(1500) component. There is evidence that the f(0)(1370) signal is resonant, from interference with f(2)(1270). There is also a state in pipi with M = 1790(-30)(+40) MeV/c(2) and Gamma = 270(-30)(+60) MeV/c(2); spin 0 is preferred over spin 2. This state, f(0)(1790), is distinct from f(0)(1710). The phiK (K) over bar data contain a strong peak due to f(2)'(1525). A shoulder on its upper side may be fitted by interference between f(0)(1500) and f(0)(1710). (C) 2004 Elsevier B.V. All rights reserved.

Published

2005

89. Study of J/ψ→ωK+K−

Author

M. Ablikim, J.Z. Bai, Y. Ban, J.G. Bian, D.V. Bugg, X. Cai, J.F. Chang, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Jun Chen, M.L. Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, H.L. Dai, Y.S. Dai, Z.Y. Deng, L.Y. Dong, Q.F. Dong, S.X. Du, Z.Z. Du, J. Fang, S.S. Fang, C.D. Fu, H.Y. Fu, C.S. Gao, Y.N. Gao, M.Y. Gong, W.X. Gong, S.D. Gu, Y.N. Guo, Y.Q. Guo, Z.J. Guo, F.A. Harris, K.L. He, M. He, X. He, Y.K. Heng, H.M. Hu, T. Hu, G.S. Huang, X.P. Huang, X.T. Huang, X.B. Ji, C.H. Jiang, X.S. Jiang, D.P. Jin, S. Jin, Y. Jin, Yi Jin, Y.F. Lai, F. Li, G. Li, H.H. Li, J. Li, J.C. Li, Q.J. Li, R.Y. Li, S.M. Li, W.D. Li, W.G. Li, X.L. Li, X.Q. Li, Y.L. Li, Y.F. Liang, H.B. Liao, C.X. Liu, F. Liu, Fang Liu, H.H. Liu, H.M. Liu, J. Liu, J.B. Liu, J.P. Liu, R.G. Liu, Z.A. Liu, Z.X. Liu, F. Lu, G.R. Lu, H.J. Lu, J.G. Lu, C.L. Luo, L.X. Luo, X.L. Luo, F.C. Ma, H.L. Ma, J.M. Ma, L.L. Ma, Q.M. Ma, X.B. Ma, X.Y. Ma, Z.P. Mao, X.H. Mo, J. Nie, Z.D. Nie, S.L. Olsen, H.P. Peng, N.D. Qi, C.D. Qian, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, D.L. Shen, X.Y. Shen, H.Y. Sheng, F. Shi, X. Shi, H.S. Sun, J.F. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, X. Tang, N. Tao, Y.R. Tian, G.L. Tong, G.S. Varner, D.Y. Wang, J.Z. Wang, K. Wang, L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, S.Z. Wang, W.F. Wang, Y.F. Wang, Z. Wang, Z.Y. Wang, Zhe Wang, Zheng Wang, C.L. Wei, D.H. Wei, N. Wu, Y.M. Wu, X.M. Xia, X.X. Xie, B. Xin, G.F. Xu, H. Xu, S.T. Xue, M.L. Yan, F. Yang, H.X. Yang, J. Yang, Y.X. Yang, M. Ye, M.H. Ye, Y.X. Ye, L.H. Yi, Z.Y. Yi, C.S. Yu, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, S.L. Zang, Y. Zeng, Yu Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Y. Zhang, J. Zhang, J.W. Zhang, J.Y. Zhang, Q.J. Zhang, S.Q. Zhang, X.M. Zhang, X.Y. Zhang, Y.Y. Zhang, Yiyun Zhang, Z.P. Zhang, Z.Q. Zhang, D.X. Zhao, J.B. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, X.J. Zhao, Y.B. Zhao, Z.G. Zhao, H.Q. Zheng, J.P. Zheng, L.S. Zheng, Z.P. Zheng, X.C. Zhong, B.Q. Zhou, G.M. Zhou, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Yingchun Zhu, Z.A. Zhu, B.A. Zhuang, X.A. Zhuang, and B.S. Zou

Subjects

Physics, Nuclear and High Energy Physics, Nuclear magnetic resonance, Branching fraction, Analytical chemistry, Dalitz plot, Omega, Bar (unit)

Abstract

New data are presented on J/psi --> omegaK(+)K(-) from a sample of 58M J/psi events in the upgraded BES II detector at the BEPC. There is a conspicuous signal for f(0)(1710) --> K+K- and a peak at higher mass which may be fitted with f(2)(2150) --> K (K) over bar. From a combined analysis with omegapi(+)pi(-) data, the branching ratio BR(f(0)(1710) --> pipi)/BR(f(0)(1710) --> K (K) over bar) is < 0.11 at the 95% confidence level. (C) 2004 Elsevier B.V. All rights reserved.

Published

2004

90. Measurement of cross sections for D0D¯0 and D+D− production in e+e− annihilation at s=3.773 GeV

Author

M. Ablikim, J.Z. Bai, Y. Ban, J.G. Bian, X. Cai, J.F. Chang, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Jun Chen, M.L. Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, H.L. Dai, Y.S. Dai, Z.Y. Deng, L.Y. Dong, S.X. Du, Z.Z. Du, J. Fang, S.S. Fang, C.D. Fu, H.Y. Fu, C.S. Gao, Y.N. Gao, M.Y. Gong, W.X. Gong, S.D. Gu, Y.N. Guo, Y.Q. Guo, K.L. He, M. He, X. He, Y.K. Heng, H.M. Hu, T. Hu, L. Huang, X.P. Huang, X.B. Ji, Q.Y. Jia, C.H. Jiang, X.S. Jiang, D.P. Jin, S. Jin, Y. Jin, Y.F. Lai, F. Li, G. Li, H.H. Li, J. Li, J.C. Li, Q.J. Li, R.B. Li, R.Y. Li, S.M. Li, W.G. Li, X.L. Li, X.Q. Li, X.S. Li, Y.F. Liang, H.B. Liao, C.X. Liu, F. Liu, Fang Liu, H.M. Liu, J.B. Liu, J.P. Liu, R.G. Liu, Z.A. Liu, Z.X. Liu, F. Lu, G.R. Lu, J.G. Lu, C.L. Luo, X.L. Luo, F.C. Ma, J.M. Ma, L.L. Ma, Q.M. Ma, X.Y. Ma, Z.P. Mao, X.H. Mo, J. Nie, Z.D. Nie, H.P. Peng, N.D. Qi, C.D. Qian, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, D.L. Shen, X.Y. Shen, H.Y. Sheng, F. Shi, X. Shi, H.S. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, X. Tang, N. Tao, Y.R. Tian, G.L. Tong, D.Y. Wang, J.Z. Wang, K. Wang, L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, S.Z. Wang, W.F. Wang, Y.F. Wang, Zhe Wang, Z. Wang, Zheng Wang, Z.Y. Wang, C.L. Wei, D.H. Wei, N. Wu, Y.M. Wu, X.M. Xia, X.X. Xie, B. Xin, G.F. Xu, H. Xu, Y. Xu, S.T. Xue, M.L. Yan, F. Yang, H.X. Yang, J. Yang, S.D. Yang, Y.X. Yang, M. Ye, M.H. Ye, Y.X. Ye, L.H. Yi, Z.Y. Yi, C.S. Yu, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, Q. Yue, S.L. Zang, Yu. Zeng, Y. Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Y. Zhang, J. Zhang, J.Y. Zhang, J.W. Zhang, L.S. Zhang, Q.J. Zhang, S.Q. Zhang, X.M. Zhang, X.Y. Zhang, Y.J. Zhang, Y.Y. Zhang, Yiyun Zhang, Z.P. Zhang, Z.Q. Zhang, D.X. Zhao, J.B. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, X.J. Zhao, Y.B. Zhao, H.Q. Zheng, J.P. Zheng, L.S. Zheng, Z.P. Zheng, X.C. Zhong, B.Q. Zhou, G.M. Zhou, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Yingchun Zhu, Z.A. Zhu, B.A. Zhuang, and B.S. Zou

Subjects

Physics, Nuclear physics, Nuclear and High Energy Physics, Cross section (physics), Particle physics, Annihilation, Pair production, Electron–positron annihilation, Hadron, Extrapolation, Production (computer science), Charm (quantum number)

Abstract

The cross sections for D 0 D ¯ 0 and D + D − production at 3.773 GeV have been measured with BES-II detector at BEPC. These measurements are made by analyzing a data sample of about 17.3 pb −1 collected at the center-of-mass energy of 3.773 GeV. Observed cross sections for the charm pair production are radiatively corrected to obtain the tree level cross section for D D ¯ production. A measurement of the total tree level hadronic cross section is obtained from the tree level D D ¯ cross section and an extrapolation of the R u d s below the open charm threshold.

Published

2004

91. Direct measurements of the branching fractions for D0→K−e+νe and D0→π−e+νe and determinations of the form factors f+K(0) and f+π(0)

Author

Yudan Wang, Z. A. Zhu, Z. Y. Yi, H. S. Chen, B.S. Zou, Feng Shi, Guangzhao Zhou, Z.Q. Zhang, Y. Jin, Qiyang Zhang, J. B. Zhao, P. P. Zhao, N. Wu, Lei Zhang, M. Ablikim, G. Rong, J. Z. Wang, Zhenyu Zhang, Jun-Bing Ma, Y. F. Liang, D. X. Zhao, B. Y. Zhang, D. P. Jin, X. Y. Shen, X. Y. Ma, Hangxu Li, P. Wang, W. X. Gong, Jiemin Li, D. H. Zhang, C. S. Yu, Y.N. Gao, C. D. Qian, W. R. Zhao, X. Shi, K. L. He, S. D. Yang, Xingzhu Cui, S. L. Zang, F. Yang, J. G. Bian, Zujian Wang, Kelin Wang, J. C. Chen, Jiang Changhui, Zhi-Jun Sun, F. Lu, Z. D. Nie, M. L. Chen, X. Q. Li, F. Y. Li, Y. Q. Guo, Gongru Lu, J. P. Liu, X. X. Xie, X. S. Jiang, Y.X. Yang, R. Y. Li, H. L. Dai, X. H. He, Yu Zeng, Y. B. Chen, Y.R. Tian, H. Qin, Cunfeng Wei, Y. J. Zhang, J. Fang, L. S. Zheng, Ning Zhou, J. W. Zhao, H. Y. Zhang, S. Z. Wang, H. Xu, Y. F. Lai, Q. M. Zhu, X. J. Zhao, H.B. Liao, W. F. Wang, J. W. Zhang, S. T. Xue, H.Q. Zheng, Zheng Wang, S. P. Chi, Haiwen Liu, Y. C. Zhu, M. Z. Wang, G. W. Yu, Q. M. Ma, C. Z. Yuan, X. M. Xia, Jin Chen, H. S. Sun, K. J. Zhu, J. Y. Zhang, Y. Xu, H. X. Yang, Haiping Peng, S. S. Fang, Y. Yuan, Y. S. Zhu, J. M. Yuan, P. L. Wang, J. Nie, Y. M. Wu, H. Y. Fu, Y. K. Heng, Y. Y. Zhang, Xunchao Zhang, Z. Y. Wang, J. G. Lu, Z. Y. Ren, L. Huang, J. F. Chang, L. L. Ma, Shang Lunlin, Y. S. Dai, S. Jin, W. G. Li, C. S. Gao, X. L. Luo, T. Hu, G. Li, Jinxing Zheng, X.L. Li, D. Y. Wang, XZ（蔡翔舟） Cai, Y. Z. Sun, L. S. Wang, M. G. Zhao, C. D. Fu, Yiyun Zhang, Z. Y. Deng, Y. X. Ye, S.S. Sun, Lianyou Shan, G. F. Xu, R. B. Li, L. P. Zhou, F. C. Ma, X. C. Zhong, L. H. Yi, Zhe Wang, Y. P. Chu, Z. P. Mao, X. B. Ji, J. F. Qiu, Bo Xin, S. M. Li, Yangguo Zhao, Shun-Qi Zhang, M. He, Bing Zhou, D. L. Shen, C. X. Liu, J. Yang, Z. A. Liu, Y. Ban, J. Z. Bai, H. Y. Sheng, C. L. Luo, R. G. Liu, Nongjian Tao, C. C. Zhang, J. B. Liu, N. D. Qi, Z. Z. Du, Z. X. Liu, Fang Liu, S. D. Gu, Q. Yue, X.S. Li, Yingchun Zhu, J. C. Li, X. Tang, Xuan Zhang, Qingying Jia, Fei-Fei Liu, Y. Zeng, Jun Chen, H. M. Hu, M. Y. Gong, S. X. Du, M. L. Yan, B. X. Zhang, Hao-Ze Chen, Juan Zhang, Y. N. Guo, M. H. Ye, L. Y. Dong, Z. P. Zheng, Xiru Huang, G. L. Tong, B. A. Zhuang, X. H. Mo, Q. J. Li, and D. H. Wei

Subjects

Physics, Nuclear and High Energy Physics, Meson, Electron–positron annihilation, Analytical chemistry, Atomic physics, Branching (polymer chemistry)

Abstract

The absolute branching fractions for the decays D 0 → K − e + ν e and D 0 → π − e + ν e are determined using 7584 ± 198 ± 341 singly tagged D ¯ 0 sample from the data collected around 3.773 GeV with the BES-II detector at the BEPC. In the system recoiling against the singly tagged D ¯ 0 meson, 104.0 ± 10.9 events for D 0 → K − e + ν e and 9.0 ± 3.6 events for D 0 → π − e + ν e decays are observed. Those yield the absolute branching fractions to be BF ( D 0 → K − e + ν e ) = ( 3.82 ± 0.40 ± 0.27 ) % and BF ( D 0 → π − e + ν e ) = ( 0.33 ± 0.13 ± 0.03 ) % . The vector form factors are determined to be | f + K ( 0 ) | = 0.78 ± 0.04 ± 0.03 and | f + π ( 0 ) | = 0.73 ± 0.14 ± 0.06 . The ratio of the two form factors is measured to be | f + π ( 0 ) / f + K ( 0 ) | = 0.93 ± 0.19 ± 0.07 .

Published

2004

92. Search for the lepton flavor violation processes J/ψ→ μτ and eτ

Author

Y. B. Zhao, Feng Shi, X. J. Zhao, F. C. Ma, F. Yang, S. D. Yang, Q. M. Zhu, F. Y. Li, J. P. Liu, Y. C. Xu, H. L. Dai, M. Z. Wang, K. L. He, J. W. Zhao, D. X. Zhao, B. Y. Zhang, H. S. Sun, Hangxu Li, Jiemin Li, S. X. Du, Haiping Peng, Guangzhao Zhou, G. W. Yu, S. T. Xue, Hao-Ze Chen, L. L. Ma, J. G. Lu, Q. J. Li, H. Y. Zhang, Haiwen Liu, J. Nie, G. S. Huang, J. F. Qiu, M. L. Yan, H. S. Chen, L. Huang, Y. Q. Guo, Y.X. Yang, Y. S. Dai, Y. B. Chen, C. S. Gao, Jinxing Zheng, D. H. Wei, T. Hu, XZ（蔡翔舟） Cai, J. Y. Zhang, H. Y. Sheng, M. H. Ye, B.S. Zou, J. F. Chang, Z.Q. Zhang, Y. F. Lai, H. X. Yang, H.S. Xu, W. F. Wang, J. B. Zhao, N. D. Qi, L. Y. Dong, S.S. Sun, Z. Y. Yi, Yiyun Zhang, C. L. Luo, Z. Y. Wang, Z. A. Liu, Lianyou Shan, Y. K. Heng, L. P. Zhou, Y. Y. Zhang, Y. X. Ye, Xunchao Zhang, Y. C. Zhu, X. Y. Shen, X. S. Jiang, Xingzhu Cui, Y. Ban, G. F. Xu, Jun-Bing Ma, S. M. Li, Z. P. Mao, X. C. Zhong, Nongjian Tao, C. C. Zhang, P. L. Wang, Bo Xin, M. L. Chen, S. D. Gu, L. S. Wang, J. Z. Bai, X. Y. Ma, Y.R. Tian, M. G. Zhao, W. X. Gong, Q. M. Ma, S. Z. Wang, Z. Y. Ren, Bing Zhou, Q. Yue, Y. Jin, Yingchun Zhu, X. H. Mo, Z. Z. Du, S. L. Zang, Yu Zeng, S. Q. Zhang, J. G. Bian, S.L. Olsen, Z. X. Liu, Zujian Wang, Jiang Changhui, B. X. Zhang, Z. P. Zheng, Y. M. Wu, Zheng Wang, Zhenyu Zhang, F. A. Harris, Y. J. Zhang, X. Shi, Y. Yuan, Y. S. Zhu, Jin Chen, Z. G. Zhao, R. G. Liu, J. B. Liu, Y. Z. Sun, Xiru Huang, Yudan Wang, H.B. Liao, X. Q. Li, G. L. Tong, Fang Liu, Z. J. Sun, X. H. He, J. C. Chen, B. A. Zhuang, G. S. Varner, Qingying Jia, W. R. Zhao, M. He, D. L. Shen, X.S. Li, J. C. Li, S. S. Fang, J. Fang, L. S. Zheng, Z. A. Zhu, C. X. Liu, H. Qin, P. P. Zhao, Fei-Fei Liu, R. B. Li, Y. Zeng, X. M. Xia, L. H. Yi, H.Q. Zheng, Jun Chen, X. L. Luo, H. Y. Fu, Lei Zhang, W. G. Li, M. Ablikim, G. Rong, D. Y. Wang, J. Yang, Kelin Wang, Z. D. Nie, Y.N. Gao, J. Z. Wang, H. M. Hu, Y. F. Liang, D. P. Jin, C. D. Qian, D. H. Zhang, C. S. Yu, X. X. Xie, Juan Zhang, Y. N. Guo, X. Tang, Xuan Zhang, M. Y. Gong, F. Lu, Gongru Lu, C. Z. Yuan, Zhe Wang, Z.J. Guo, Qiyang Zhang, S. P. Chi, R. Y. Li, P. Wang, Cunfeng Wei, Ning Zhou, J. W. Zhang, K. J. Zhu, J. M. Yuan, Y. P. Chu, X. B. Ji, Shang Lunlin, S. Jin, G. Li, X.L. Li, C. D. Fu, Z. Y. Deng, and N. Wu

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, Particle physics, Electron–positron annihilation, Flavor, Lepton

Abstract

The lepton flavor violation processes J / ψ → μ τ and eτ are searched for using a sample of 5.8 × 10 7 J / ψ events collected with the BESII detector. Zero and one candidate events, consistent with the estimated background, are observed in J / ψ → μ τ , τ → e ν ¯ e ν τ and J / ψ → e τ , τ → μ ν ¯ μ ν τ decays, respectively. Upper limits on the branching ratios are determined to be Br ( J / ψ → μ τ ) 2.0 × 10 − 6 and Br ( J / ψ → e τ ) 8.3 × 10 − 6 at the 90% confidence level (C.L.).

Published

2004

93. The σ pole in J/ψ→ωπ+π−

Author

M. Ablikim, J.Z. Bai, Y. Ban, J.G. Bian, D.V. Bugg, X. Cai, J.F. Chang, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, Jin Chen, Jun Chen, M.L. Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, H.L. Dai, Y.S. Dai, Z.Y. Deng, L.Y. Dong, S.X. Du, Z.Z. Du, J. Fang, S.S. Fang, C.D. Fu, H.Y. Fu, C.S. Gao, Y.N. Gao, M.Y. Gong, W.X. Gong, S.D. Gu, Y.N. Guo, Y.Q. Guo, Z.J. Guo, F.A. Harris, K.L. He, M. He, X. He, Y.K. Heng, H.M. Hu, T. Hu, G.S. Huang, L. Huang, X.P. Huang, X.B. Ji, Q.Y. Jia, C.H. Jiang, X.S. Jiang, D.P. Jin, S. Jin, Y. Jin, Y.F. Lai, F. Li, G. Li, H.H. Li, J. Li, J.C. Li, Q.J. Li, R.B. Li, R.Y. Li, S.M. Li, W.G. Li, X.L. Li, X.Q. Li, X.S. Li, Y.F. Liang, H.B. Liao, C.X. Liu, F. Liu, Fang Liu, H.M. Liu, J.B. Liu, J.P. Liu, R.G. Liu, Z.A. Liu, Z.X. Liu, F. Lu, G.R. Lu, J.G. Lu, C.L. Luo, X.L. Luo, F.C. Ma, J.M. Ma, L.L. Ma, Q.M. Ma, X.Y. Ma, Z.P. Mao, X.H. Mo, J. Nie, Z.D. Nie, S.L. Olsen, H.P. Peng, N.D. Qi, C.D. Qian, H. Qin, T.N. Ruan, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, D.L. Shen, X.Y. Shen, H.Y. Sheng, F. Shi, X. Shi, H.S. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, X. Tang, N. Tao, Y.R. Tian, G.L. Tong, G.S. Varner, D.Y. Wang, J.Z. Wang, K. Wang, L. Wang, L.S. Wang, M. Wang, P. Wang, P.L. Wang, S.Z. Wang, W.F. Wang, Y.F. Wang, Zhe Wang, Z. Wang, Zheng Wang, Z.Y. Wang, C.L. Wei, D.H. Wei, N. Wu, Y.M. Wu, X.M. Xia, X.X. Xie, B. Xin, G.F. Xu, H. Xu, Y. Xu, S.T. Xue, M.L. Yan, F. Yang, H.X. Yang, J. Yang, S.D. Yang, Y.X. Yang, M. Ye, M.H. Ye, Y.X. Ye, L.H. Yi, Z.Y. Yi, C.S. Yu, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, Q. Yue, S.L. Zang, Yu Zeng, Y. Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Y. Zhang, J. Zhang, J.Y. Zhang, J.W. Zhang, L.S. Zhang, Q.J. Zhang, S.Q. Zhang, X.M. Zhang, X.Y. Zhang, Y.J. Zhang, Y.Y. Zhang, Yiyun Zhang, Z.P. Zhang, Z.Q. Zhang, D.X. Zhao, J.B. Zhao, J.W. Zhao, M.G. Zhao, P.P. Zhao, W.R. Zhao, X.J. Zhao, Y.B. Zhao, Z.G. Zhao, H.Q. Zheng, J.P. Zheng, L.S. Zheng, Z.P. Zheng, X.C. Zhong, B.Q. Zhou, G.M. Zhou, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Y.C. Zhu, Y.S. Zhu, Yingchun Zhu, Z.A. Zhu, B.A. Zhuang, and B.S. Zou

Subjects

Nuclear physics, Systematic error, Physics, Nuclear and High Energy Physics, Angular distribution, Electron–positron annihilation, Partial wave analysis, Pi, Resonance, Sigma, Omega

Abstract

Using a sample of 58 million J/psi events recorded in the BESII detector, the decay J/psi --> omegapi(+)pi(-) is studied. There are conspicuous omegaf(2)(1270) and b(1)(1235)pi signals. At low pipi mass, a large, broad peak due to the sigma is observed, and its pole position is determined to be (541 +/- 39) - i (252 +/- 42) MeV from the mean of six analyses. The errors, which are dominated by the systematic errors, cover the statistical and systematic errors in the six analyses, as well as the observed variation of the six analyses. (C) 2004 Elsevier B.V. All rights reserved.

Published

2004

94. Factors governing in situ fibre formation in LCP/PC blends☆

Author

Xiao Hu, Kam Chiu Tam, Y.X Yang, Yee Cheong Lam, Sunil C. Joshi, and C.Y Yue

Subjects

In situ, chemistry.chemical_classification, Materials science, Polymer, Rheology, chemistry, Mechanics of Materials, Liquid crystal, Phase (matter), Ceramics and Composites, Interphase, Polymer blend, Composite material, Tensile testing

Abstract

A model based on the energy concept that utilizes rheological data of the constituent polymers to predict formation of fibers of one phase in a two-component polymer blend system has been developed. This model has been verified for the formation of liquid crystal polymers (LCP) fibers for an LCP/PC blend system. Tensile test data and SEM fractographs from injection molded samples revealed that the model predictions were consistent with the experimental findings.

Published

2004

95. A study of J/ψ→γγV(ρ,φ) decays with the BESII detector

Author

J.Z. Bai, Y. Ban, J.G. Bian, X. Cai, J.F. Chang, H.F. Chen, H.S. Chen, H.X. Chen, J.C. Chen, J. Chen, M.L. Chen, Y.B. Chen, S.P. Chi, Y.P. Chu, X.Z. Cui, H.L. Dai, Y.S. Dai, Z.Y. Deng, L.Y. Dong, S.X. Du, Z.Z. Du, J. Fang, S.S. Fang, C.D. Fu, H.Y. Fu, L.P. Fu, C.S. Gao, M.L. Gao, Y.N. Gao, M.Y. Gong, W.X. Gong, S.D. Gu, Y.N. Guo, Y.Q. Guo, S.W. Han, J. He, K.L. He, M. He, X. He, Y.K. Heng, H.M. Hu, T. Hu, G.S. Huang, L. Huang, X.P. Huang, X.B. Ji, Q.Y. Jia, C.H. Jiang, X.S. Jiang, D.P. Jin, S. Jin, Y. Jin, Y.F. Lai, F. Li, G. Li, H.H. Li, J. Li, J.C. Li, Q.J. Li, R.B. Li, R.Y. Li, S.M. Li, W. Li, W.G. Li, X.L. Li, X.Q. Li, X.S. Li, Y.F. Liang, H.B. Liao, C.X. Liu, Fang Liu, F. Liu, H.M. Liu, J.B. Liu, J.P. Liu, R.G. Liu, Y. Liu, Z.A. Liu, Z.X. Liu, G.R. Lu, F. Lu, J.G. Lu, C.L. Luo, X.L. Luo, F.C. Ma, J.M. Ma, L.L. Ma, X.Y. Ma, Z.P. Mao, X.C. Meng, X.H. Mo, J. Nie, Z.D. Nie, H.P. Peng, N.D. Qi, C.D. Qian, H. Qin, J.F. Qiu, Z.Y. Ren, G. Rong, L.Y. Shan, L. Shang, D.L. Shen, X.Y. Shen, H.Y. Sheng, F. Shi, X. Shi, L.W. Song, H.S. Sun, S.S. Sun, Y.Z. Sun, Z.J. Sun, X. Tang, N. Tao, Y.R. Tian, G.L. Tong, D.Y. Wang, J.Z. Wang, L. Wang, L.S. Wang, M. Wang, Meng Wang, P. Wang, P.L. Wang, S.Z. Wang, W.F. Wang, Y.F. Wang, Zhe Wang, Z. Wang, Zheng Wang, Z.Y. Wang, C.L. Wei, N. Wu, Y.M. Wu, X.M. Xia, X.X. Xie, B. Xin, G.F. Xu, H. Xu, Y. Xu, S.T. Xue, M.L. Yan, W.B. Yan, F. Yang, H.X. Yang, J. Yang, S.D. Yang, Y.X. Yang, L.H. Yi, Z.Y. Yi, M. Ye, M.H. Ye, Y.X. Ye, C.S. Yu, G.W. Yu, C.Z. Yuan, J.M. Yuan, Y. Yuan, Q. Yue, S.L. Zang, Y. Zeng, B.X. Zhang, B.Y. Zhang, C.C. Zhang, D.H. Zhang, H.Y. Zhang, J. Zhang, J.M. Zhang, J.Y. Zhang, J.W. Zhang, L.S. Zhang, Q.J. Zhang, S.Q. Zhang, X.M. Zhang, X.Y. Zhang, Yiyun Zhang, Y.J. Zhang, Y.Y. Zhang, Z.P. Zhang, Z.Q. Zhang, D.X. Zhao, J.B. Zhao, J.W. Zhao, P.P. Zhao, W.R. Zhao, X.J. Zhao, Y.B. Zhao, Z.G. Zhao, H.Q. Zheng, J.P. Zheng, L.S. Zheng, Z.P. Zheng, X.C. Zhong, B.Q. Zhou, G.M. Zhou, L. Zhou, N.F. Zhou, K.J. Zhu, Q.M. Zhu, Yingchun Zhu, Y.C. Zhu, Y.S. Zhu, Z.A. Zhu, B.A. Zhuang, and B.S. Zou

Subjects

Physics, Nuclear physics, Particle physics, Nuclear and High Energy Physics, Meson, Glueball, Branching fraction, Electron–positron annihilation, Detector, Mass spectrum, Radiative transfer, Resonance

Abstract

Using a sample of 58×10 6 J / ψ events collected with the BESII detector, radiative decays J / ψ → γγV , where V = ρ or φ , are studied. A resonance around 1420 MeV/ c 2 ( X (1424)) is observed in the γρ mass spectrum. Its mass and width are measured to be 1424±10(stat)±11(sys) MeV/ c 2 and 101.0±8.8±8.8 MeV/ c 2 , respectively, and its branching ratio B ( J / ψ → γX (1424)→ γγρ ) is determined to be (1.07±0.17±0.11)×10 −4 . A search for X (1424)→ γφ yields a 95% C.L. upper limit B ( J / ψ → γX (1424)→ γγφ ) −4 .

Published

2004

96. Search for K0SK0S in J/ψ and ψ(2S) decays

Author

L. P. Zhou, Y. Yuan, Y. S. Zhu, Z. P. Mao, N. Wu, Z. Y. Yi, Zujian Wang, Jiang Changhui, X. H. Mo, L. S. Wang, M. H. Ye, Z. A. Liu, K. L. He, S. W. Han, J. M. Zhang, Y. Ban, J. Z. Bai, J. He, H. Y. Zhang, X. S. Jiang, Z. P. Zheng, Haiwen Liu, G. S. Huang, S. X. Du, W. R. Zhao, Feng Shi, J. Y. Zhang, M. L. Yan, Xiru Huang, G. L. Tong, Y. Jin, Xingzhu Cui, B. A. Zhuang, Y. K. Heng, Y. Y. Zhang, Z. Z. Du, Z. X. Liu, Guangzhao Zhou, S. D. Gu, Q. Yue, J. C. Li, Yingchun Zhu, X. Tang, Xuan Zhang, B.S. Zou, Z.Q. Zhang, Zheng Wang, Zhenyu Zhang, J. F. Chang, X. M. Xia, M. Y. Gong, J. C. Chen, Yiyun Zhang, J. Fang, L. S. Zheng, Xunchao Zhang, Juan Zhang, Z. D. Nie, Y. X. Ye, Y.R. Tian, Y. N. Guo, Y.N. Gao, M. L. Gao, H. S. Chen, J. B. Zhao, G. S. Varner, Qingying Jia, Z.J. Guo, S. L. Zang, J. Nie, X. H. He, Y. Q. Guo, Y.X. Yang, C. D. Qian, Q. J. Li, Qiyang Zhang, S. M. Li, Y. B. Chen, X. Y. Shen, Y. C. Zhu, Y. Xu, H. Y. Fu, Jun Chen, Bing Zhou, H.Q. Zheng, H.S. Xu, Y. F. Lai, L. Huang, L. L. Ma, Y. M. Wu, S.L. Olsen, W. F. Wang, Y. B. Zhao, P. Wang, Y. S. Dai, Bo Xin, J. G. Lu, P. L. Wang, P. P. Zhao, Yudan Wang, S. Q. Zhang, C. S. Gao, X. J. Zhao, J. Chen, J. Z. Wang, W. D. Li, Jinxing Zheng, Meng Wang, H. X. Yang, Y. Z. Sun, T. Hu, L. Y. Dong, Y. F. Liang, H.B. Liao, XZ（蔡翔舟） Cai, D. P. Jin, Lei Zhang, Z. A. Zhu, F. Yang, G. Rong, R. Y. Li, G. F. Xu, H. M. Hu, H. Qin, D. X. Zhao, Cunfeng Wei, D. H. Zhang, C. S. Yu, S.S. Sun, J. W. Zhao, S. D. Yang, G. W. Yu, Lianyou Shan, Ning Zhou, B. Y. Zhang, Jun-Bing Ma, Hangxu Li, Jiemin Li, J. W. Zhang, B. X. Zhang, Hao-Ze Chen, J. G. Bian, X. C. Zhong, Z. Y. Ren, F. A. Harris, W. G. Li, D. Y. Wang, W. B. Yan, X. Y. Ma, W. X. Gong, F. Lu, F. Y. Li, J. P. Liu, Fei-Fei Liu, X. Shi, H. L. Dai, F. C. Ma, Q. M. Zhu, Y. Zeng, M. Z. Wang, H. S. Sun, Haiping Peng, C. Z. Yuan, Zhe Wang, J. F. Qiu, L. P. Fu, C. L. Luo, Nongjian Tao, C. C. Zhang, Z. G. Zhao, Fang Liu, Z. J. Sun, X.S. Li, Gongru Lu, S. P. Chi, K. J. Zhu, J. M. Yuan, Shang Lunlin, S. Jin, G. Li, X.L. Li, C. D. Fu, Z. Y. Deng, Y. P. Chu, X. B. Ji, S. T. Xue, X. L. Luo, Z. Y. Wang, S. Z. Wang, L. W. Song, M. L. Chen, Y. J. Zhang, R. B. Li, X. Q. Li, H. Y. Sheng, L. H. Yi, N. D. Qi, S. S. Fang, Y. B. Liu, J. Yang, M. He, D. L. Shen, R. G. Liu, J. B. Liu, C. X. Liu, X. X. Xie, and X. C. Meng

Subjects

Physics, Nuclear physics, Nuclear and High Energy Physics, Spectrometer, Electron–positron annihilation, Atomic physics

Abstract

The CP violating processes J / ψ → K 0 S K 0 S and ψ (2 S )→ K 0 S K 0 S are searched for using samples of 58 million J / ψ and 14 million ψ (2 S ) events collected with the Beijing spectrometer at the Beijing electron–positron collider. No signal is observed, and upper limits on the decay branching ratios are determined to be B (J/ψ→K 0 S K 0 S ) −6 and B (ψ(2S)→K 0 S K 0 S ) −6 at the 95% confidence level.

Published

2004

97. Electrical property of nanocrystalline γ-Fe2O3 under high pressure

Author

Y.X. Yang, Yongsheng Zhang, Ke Yu, Chunxiao Gao, Chunhe Zang, Dongmei Zhang, and Yonghao Han

Subjects

Phase transition, Materials science, Condensed matter physics, Maghemite, engineering.material, Hematite, Conductivity, Condensed Matter Physics, Nanocrystalline material, Electronic, Optical and Magnetic Materials, Discontinuity (geotechnical engineering), Electrical resistivity and conductivity, High pressure, visual_art, engineering, visual_art.visual_art_medium, Electrical and Electronic Engineering

Abstract

Using a microcircuit fabricated on a diamond anvil cell, in situ conductivity measurements on nanophase (NP) γ-Fe2O3 are obtained under high pressure. For NP γ-Fe2O3, the abrupt increase in electrical conductivity occurs at a pressure of 21.3 GPa, corresponding to a transition from maghemite to hematite. Above 26.4 GPa, conductivity increases smoothly with increasing pressure. No distinct abnormal change is observed during decompression, indicating that transformation is irreversible. The temperature-dependence of the conductivity of NP γ-Fe2O3 was investigated at several pressures, indicating the electrical conductivity of the sample increases with increasing pressure and temperature, and that a remarkable phenomenon of discontinuity occurs at 400 K. The abnormal change is attributed to the electronic phase transitions of NP γ-Fe2O3 due to the variation of inherent cation vacancies. Besides, the temperature-dependence of the electrical conductivity displays semiconductor-like behavior before 33.0 GPa.

Published

2012

98. ChemInform Abstract: Controlled Synthesis of Urchin-Like Bi2S3 via Hydrothermal Method

Author

Changqing Wang, Chunhe Zang, Y.X. Yang, Fengjian Su, Y. S. Zhang, C. J. Tang, and Zhengjun Zong

Subjects

chemistry.chemical_compound, Nanostructure, Aqueous solution, Thiourea, Chemical engineering, Chemistry, Nanowire, Nanorod, General Medicine, Porosity, Hydrothermal circulation, Autoclave

Abstract

Spherical urchin-like Bi2S3 flowers consisting of porous nanorods, solid nanorods, or nanowires which grow radially from the center of the nanostructures toward all directions are hydrothermally prepared from aqueous solutions of thiourea and Bi(NO3)3 (autoclave, 140 °C, 0.5—12 h).

Published

2010

99. Solution-based processing of YBa2Cu3Ox superconducting thin films

Author

Steven J. Milne, M. A. Howson, and Y.X. Yang

Subjects

Materials science, Argon, Oxide, Analytical chemistry, chemistry.chemical_element, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, chemistry, Phase (matter), Materials Chemistry, Ceramics and Composites, Cubic zirconia, Crystallite, Thin film, Thermal analysis, Yttria-stabilized zirconia

Abstract

A solution route based on metal acetate precursors was developed for preparation of YBa2Cu3Ox thin films. Solubility of the precursors in the methoxyethanol solvent employed was improved by incorporation of triethanolamine as a chelating agent. Conversion of the solution to an oxide superconductor was followed by thermal analysis, X-ray diffraction and electron microscopy techniques. For high Tc thin film formation, an inert firing atmosphere (argon) was helpful for development of the superconducting phase. For conventional oxygen processing, temperatures up to 950°C are usually required to achieve the desired superconducting properties. Using argon atmospheres, lower firing temperatures, ∼ 800–850°C, are possible, leading to reduced film-substrate interaction. The highest Tc(0) achieved was 84 K for c-axis orientated films on yttria stabilised polycrystalline zirconia (YSZ) substrates. The critical current density, jc, was 500 A cm−2 at 77 K.

Published

1992

100. Synthesis of cubic aluminum nitride by carbothermal nitridation reaction

Author

Y.X. Yang, G. Sánchez, Wei Wang, J. Esteve, M.C. Polo, L. Fang, J. Wang, and P.D. Ding

Subjects

Reaction mechanism, Materials science, Aluminium nitride, Mechanical Engineering, Mineralogy, chemistry.chemical_element, General Chemistry, Nitride, Chemical reaction, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, chemistry, Chemical engineering, Aluminium, visual_art, Materials Chemistry, Aluminium oxide, visual_art.visual_art_medium, Ceramic, Electrical and Electronic Engineering, Nitriding

Abstract

Cubic aluminum nitride (AlN) was synthesized by the carbothermal nitridation reaction of aluminum oxide (Al 2 O 3 ). The effects of Al 2 O 3 particle size, reaction temperature and reaction time on the synthesis of cubic AlN were investigated, and the reaction mechanism was also analyzed. The results showed that cubic AlN could be formed at a lower temperature with fine Al 2 O 3 powder than with coarse Al 2 O 3 powder. The cubic AlN may be the product of Al 23 O 27 N 5 synthesized from Al 2 O 3 and hexagonal AlN, and transforms into hexagonal AlN at temperatures above 1800°C.

Published

1999