Your search keyword '"Song, Jiage"' showing total 26 results

1. Fungal diversity notes 1611–1716: taxonomic and phylogenetic contributions on fungal genera and species emphasis in south China

Author

Senanayake, Indunil C., Rossi, Walter, Leonardi, Marco, Weir, Alex, McHugh, Mark, Rajeshkumar, Kunhiraman C., Verma, Rajnish K., Karunarathna, Samantha C., Tibpromma, Saowaluck, Ashtekar, Nikhil, Ashtamoorthy, Sreejith K., Raveendran, Sanjay, Kour, Gurmeet, Singh, Aishwarya, De la Peña-Lastra, Saúl, Mateos, Antonio, Kolařík, Miroslav, Antonín, Vladimír, Ševčíková, Hana, Esteve-Raventós, Fernando, Larsson, Ellen, Pancorbo, Fermín, Moreno, Gabriel, Altés, Alberto, Turégano, Yolanda, Du, Tian-Ye, Lu, Li, Li, Qi-Rui, Kang, Ji-Chuan, Gunaseelan, Sugantha, Kezo, Kezhocuyi, Kaliyaperumal, Malarvizhi, Fu, Jizhen, Samarakoon, Milan C., Gafforov, Yusufjon, Teshaboeva, Shakhnoza, Kunjan, Pradeep C., Chamaparambath, Arya, Flakus, Adam, Etayo, Javier, Rodriguez-Flakus, Pamela, Zhurbenko, Mikhail P., de Silva, Nimali I., Tennakoon, Danushka S., Latha, K. P. Deepna, Manimohan, Patinjareveettil, Raj, K. N. Anil, Calabon, Mark S., Ahmadpour, Abdollah, Heidarian, Zeinab, Alavi, Zahra, Alavi, Fatemeh, Ghosta, Youbert, Azizi, Razmig, Luo, Mei, Zhao, Min-Ping, Kularathnage, Nuwan D., Hua, Li, Yang, Yun-Hui, Liao, Chun-Fang, Zhao, Hai-Jun, Lestari, Anis S., Jayasiri, Subashini C., Yu, Feng-Ming, Lei, Lei, Liu, Jian-Wei, Karimi, Omid, Tang, Song-Ming, Sun, Ya-Ru, Wang, Yong, Zeng, Ming, Htet, Zin H., Linaldeddu, Benedetto T., Alves, Artur, Phillips, Alan J. L., Bregant, Carlo, Montecchio, Lucio, De Kesel, André, Hustad, Vincent P., Miller, Andrew N., Fedosova, Anna G., Kučera, Viktor, Raza, Mubashar, Hussain, Muzammil, Chen, Yan-Peng, Thiyagaraja, Vinodhini, Gomdola, Deecksha, Rathnayaka, Achala R., Dissanayake, Asha J., Suwannarach, Nakarin, Hongsanan, Sinang, Maharachchikumbura, Sajeewa S. N., Dissanayake, Lakmali S., Wijayawardene, Nalin N., Phookamsak, Rungtiwa, Lumyong, Saisamorn, Jones, E. B. Gareth, Yapa, Neelamanie, Wanasinghe, Dhanushka N., Xie, Ning, Doilom, Mingkwan, Manawasinghe, Ishara S., Liu, Jian-Kui (Jack), Zhao, Qi, Xu, Biao, Hyde, Kevin D., and Song, Jiage

Published

2023

2. Selecting Solid Additives to Control the Interaction between Polymer Donors and Additives for Constructing High-Efficiency Organic Solar Cells

Author

Li, Dongxu, primary, Liang, Songting, additional, Hua, Xinqiang, additional, Fan, Bin, additional, Song, Jiage, additional, Lu, Xinhui, additional, Huang, Wenchao, additional, Yuan, Jun, additional, and Zou, Yingping, additional

Published

2024

3. Taxonomic revision of Neodidymelliopsis with N. cynanchi sp. nov., associated with Cynanchum sibiricum leaf spot in Xinjiang, China.

Author

Qian, Zhixiu, Zhang, Shanhe, Manawasinghe, Ishara S., Sun, Diangang, Song, Jiage, and Xu, Biao

Subjects

RNA polymerase II, PLANT morphology, PHYTOPATHOGENIC microorganisms, MOLECULAR phylogeny, DESERTS, LEAF spots

Abstract

During surveys of plant pathogens in the desert regions of Xinjiang Province, China, a leaf spot was observed on Cynanchum sibiricum. The suspected fungus was isolated and identified using morphology and molecular phylogeny. Morphologically, the fungus was similar to Neodidymelliopsis species. Phylogenetic analyzes of combined internal transcribed spacer (ITS); the large subunit of the ribosomal rDNA (LSU); RNA polymerase II the second largest subunit (rpb2), and β-tubulin gene (tub2) sequences showed that our isolates formed a distinct monophyletic lineage in Neodidymelliopsis. This new clade is identified as Neodidymelliopsis cynanchi sp. nov. based on the phylogenetic and morphological evidence. In addition, N. urticae is synonymized with N. cannabis based on morphology and phylogeny. Furthermore, we emphasize that in-depth revisions are required to assure the taxonomic status of N. sambuci, N. tinkyukuku and N. salvia. This is the first report of Neodidymelliopsis species associated with C. sibiricum leaf spot. The results expand our knowledge of Didymellaceae taxa and microfungi associated with desert environments in China. [ABSTRACT FROM AUTHOR]

Published

2024

4. First Report of Neophysopella vitis Causing Leaf Rust on Parthenocissus semicordata in Guangdong Province, China

Author

Zhou, Chuan-Hao, primary, Song, Jiage, additional, and Xu, Biao, additional

Published

2024

5. Taxonomic revision of Neodidymelliopsiswith N. cynanchisp. nov., associated with Cynanchum sibiricumleaf spot in Xinjiang, China

Author

Qian, Zhixiu, Zhang, Shanhe, Manawasinghe, Ishara S., Sun, Diangang, Song, Jiage, and Xu, Biao

Abstract

ABSTRACTDuring surveys of plant pathogens in the desert regions of Xinjiang Province, China, a leaf spot was observed on Cynanchum sibiricum. The suspected fungus was isolated and identified using morphology and molecular phylogeny. Morphologically, the fungus was similar to Neodidymelliopsisspecies. Phylogenetic analyzes of combined internal transcribed spacer (ITS); the large subunit of the ribosomal rDNA (LSU); RNA polymerase II the second largest subunit (rpb2), and β-tubulin gene (tub2) sequences showed that our isolates formed a distinct monophyletic lineage in Neodidymelliopsis. This new clade is identified as Neodidymelliopsis cynanchisp. nov. based on the phylogenetic and morphological evidence. In addition, N. urticaeis synonymized with N. cannabisbased on morphology and phylogeny. Furthermore, we emphasize that in-depth revisions are required to assure the taxonomic status of N. sambuci, N. tinkyukukuand N. salvia.This is the first report of Neodidymelliopsisspecies associated with C. sibiricumleaf spot. The results expand our knowledge of Didymellaceae taxa and microfungi associated with desert environments in China.

Published

2024

6. What We have Learnt from PM6:Y6.

Author

Shoaee, Safa, Luong, Hoang M., Song, Jiage, Zou, Yingping, Nguyen, Thuc‐Quyen, and Neher, Dieter

Published

2024

7. Taxonomic revision of Neodidymelliopsis with N. cynanchi sp. nov., associated with Cynanchum sibiricum leaf spot in Xinjiang, China

Author

Qian, Zhixiu, primary, Zhang, Shanhe, additional, Manawasinghe, Ishara S., additional, Sun, Diangang, additional, Song, Jiage, additional, and Xu, Biao, additional

Published

2023

8. A de novo 921 Kb microdeletion at 11q13.1 including neurexin 2 in a boy with developmental delay, deficits in speech and language without autistic behaviors

Author

Yuan, Haiming, Li, Xiaoxiu, Wang, Qingming, Yang, Wei, Song, Jiage, Hu, Xizi, and Shen, Yiping

Published

2018

9. Danggui Buxue decoction promotes angiogenesis by up-regulation of VEGFR1/2 expressions and down-regulation of sVEGFR1/2 expression in myocardial infarction rat

Author

Hu, Guanying, Yang, Peng, Zeng, Yu, Zhang, Sanyin, and Song, Jiage

Published

2018

10. Plant-Associated Novel Didymellaceous Taxa in the South China Botanical Garden (Guangzhou, China)

Author

Kularathnage, Nuwan D., primary, Senanayake, Indunil C., additional, Wanasinghe, Dhanushka N., additional, Doilom, Mingkwan, additional, Stephenson, Steven L., additional, Song, Jiage, additional, Dong, Wei, additional, and Xu, Biao, additional

Published

2023

11. Pseudocoleophoma rhapidis Kular. & K. D. Hyde 2022, sp. nov

Author

Kularathnage, Nuwan D., Wanasinghe, Dhanushka N., Senanayake, Indunil C., Yang, Yunhui, Manawasinghe, Ishara S., Phillips, Alan J. L., Hyde, Kevin D., Dong, Wei, and Song, Jiage

Subjects

Pseudocoleophoma rhapidis, Pseudocoleophoma, Ascomycota, Dothideomycetes, Fungi, Melanommataceae, Biodiversity, Pleosporales, Taxonomy

Abstract

Pseudocoleophoma rhapidis Kular. & K.D. Hyde, sp. nov. Index Fungorum number: IF559350; Facesoffungi number: FoF 10620, FIGURE 4 Etymology:—referring to the host genus, Rhapis. Pathogenic, associated with leaf spots of Rhapis excelsa (Thunb.) A. Henry, appearing as scattered, brown spots. Sexual morph: Undetermined. Asexual morph: coelomycetes. Conidiomata 150–225 × 225–300 µm (x̅ = 200 × 280 µm, n = 10), pycnidial, solitary, scattered, immersed, covered with transparent epidermal tissues, uniloculate, subglobose, black, ostiolate. Ostiole apapillate. Pycnidial wall 20–25 µm wide, consisting of 4–7 layers of brown, thick-walled, compressed cells of textura angularis. Conidiophores reduce to conidiogenous cells. Conidiogenous cells 7–10 × 13–17 µm (x̅ = 9 × 15 µm, n = 20), phialidic, hyaline, smooth-walled, doliiform. Conidia 20–25 × 10–15 µm (x̅ = 22 × 13 µm, n = 20), oblong to obovoid, hyaline, aseptate, smooth, thin-walled. Colony characters— Colonies on PDA incubating at 25 °C in dark, attenuated 2 cm after 2 weeks, circular, flat, smooth margin, slightly raised in the middle, white, without pigments in the media; reverse off-white. Cultures not sporulate within 30 days. Material examined— China, Guangdong Province, Guangzhou city, Zhongkai University of Agriculture and Engineering (23°06’28.4”N 113°16’51.6”E), as leaf spots of Rhapis excelsa (Arecaceae), 20 May 2021, N.D. Kularathnage, NDK 30-1 (ZHKU 21-0010, holotype), ex-type living culture ZHKUCC 21-0124; ibid. NDK 30-2, (ZHKU 22-0004, isotype), ex-type living culture ZHKUCC 22-0004. Disease Symptoms—Leaf-spots were observed on most of the leaves and mainly seen at the leaf margin and along the veins. The border of the spots was sometimes surrounded by a black line. Conidiomata were scattered in leaf-spots. Notes—The combined ITS, LSU, SSU and tef- 1 α multilocus analysis showed that our Pseudocoleophoma strain, P. rhapidis is phylogenetically closely related to P. bauhiniae and P. flavescens. However, P. rhapidis forms a distinct subclade with moderate support, sister to P. bauhiniae. The comparison of the DNA sequence of ITS, LSU, SSU, and tef-1α loci of Pseudocoleophoma rhapidis with P. bauhiniae revealed base pair differences of 18/526, 5/859, 12/1026 and 72/928 respectively. Pseudocoleophoma rhapidis was collected from leaf spots on Rhapis excelsa while P. bauhiniae and P. flavescens were collected from decaying pods of Bauhinia sp. and soil of a potato (Solanum tuberosum L.) field respectively (Jayasiri et al. 2019, Li et al. 2020). Pseudocoleophoma rhapidis differs from P. bauhinia in having oblong, aguttulate, large conidia while P. bauhinia has elongate, guttulate, small conidia. Pseudocoleophoma flavescens has small conidiomata and small conidia while P. bauhinia has large conidiomata and conidia (TABLE 4). Our species is the first report of a Pseudocoleophoma species collected from China. Based on morphology and phylogeny, we introduce this strain as a new species, Pseudocoleophoma rhapidis. Pathogenicity tests for Pseudocoleophoma rhapidis The inoculated leaf tissues began to show symptoms ten days after inoculation. Initial symptoms were small, circular, brown spots that expanded slowly (FIGURE 5). None of the control plants showed any disease symptoms. Disease symptoms on the host inoculated with mycelial plugs appeared later than on leaves inoculated with a conidial suspension. Leaf spots on inoculated plants were smaller than on naturally infected plants. The temperature was 15–25 °C during the test with no rainfall. The pathogen was re-isolated from the leaf spots resulting from inoculation by both methods. The culture characteristics of the re-isolated strains were consistent with the inoculated strain and ITS sequences of those strains were identical to the inoculated strain, thus fulfilling Koch’s postulates. Conidiomata similar to the holotype were observed in microscope examination of leaf spots., Published as part of Kularathnage, Nuwan D., Wanasinghe, Dhanushka N., Senanayake, Indunil C., Yang, Yunhui, Manawasinghe, Ishara S., Phillips, Alan J. L., Hyde, Kevin D., Dong, Wei & Song, Jiage, 2022, Microfungi associated with ornamental palms: Byssosphaeria phoenicis sp. nov. (Melanommataceae) and Pseudocoleophoma rhapidis sp. nov. (Dictyosporiaceae) from south China, pp. 149-169 in Phytotaxa 568 (2) on pages 158-162, DOI: 10.11646/phytotaxa.568.2.2, http://zenodo.org/record/7192811, {"references":["Barr, M. E. (1984) Herpotrichia and its segregates. Mycotaxon 20: 1 - 38.","Chen, C. Y. & Hsieh, W. H. (2004) Byssosphaeria and Herpotrichia from Taiwan, with notes on the taxonomic relationship between these two genera. Sydowia 56: 24 - 38.","Li, W. Y. & Zhuang, W. Y. (2008) Notes on the genus Byssosphaeria (Melanommataceae) from China. Mycosystema 27: 48 - 53.","Tennakoon, D. S., Jeewon, R., Chang-Hsin, K. & Hyde, K. D. (2018) Phylogenetic and morphological characterization of Byssosphaeria macarangae sp. nov., and B. taiwanense sp. nov. from Macaranga tanarius. Phytotaxa 364 (3): 211 - 226. https: // doi. org / 10.11646 / Phytotaxa. 364.3.1","Liu, J. K., Hyde, K. D., Jones, E. B. G., Ariyawansa, H. A., Bhat, D. J., Boonmee, S., Maharachchikumbura, S. S. N., McKenzie, E. H. C., Phookamsak, R., Phukhamsakda, C., Shenoy, B. D., Abdel-Wahab, M. A., Buyck, B., Chen, J., Chethana, K. W. T., Singtripop, C., Dai, D. Q., Dai, Y. C., Daranagama, D. A., Dissanayake, A. J., Doilom, M., D'souza, M. J., Fan, X. L., Goonasekara, I. D., Hirayama, K., Hongsanan, S., Jayasiri, S. C., Jayawardena, R. S., Karunarathna, S. C., Li, W. J., Mapook, A., Norphanphoun, C., Pang, K. L., Perera, R. H., Persoh, D., Pinruan, U., Senanayake, I. C., Somrithipol, S., Suetrong, S., Tanaka, K., Thambugala, K. M., Tian, Q., Tibpromma, S., Udayanga, D., Wijayawardene, N. N., Wanasinghe, D., Wisitrassameewong, K., Zeng, X. Y., Abdel-Aziz, F. A., Adamcik, S., Bahkali, A. H., Boonyuen, N., Bulgakov, T., Callac, P., Chomnunti, P., Greiner, K., Hashimoto, A., Hofstetter, V., Kang, J. C., Lewis, D., Li, X. H., Liu, X. Z., Liu, Z. Y., Matsumura, M., Mortimer, P. E., Rambold, G., Randrianjohany, E., Sato, G., Sri-Indrasutdhi, V., Tian, C. M., Verbeken, A., von Brackel, W., Wang, Y., Wen, T. C., Xu, J. C., Yan, J. Y., Zhao, R. L. & Camporesi, E. (2015) Fungal Diversity Notes 1 - 110: Taxonomic and phylogenetic contributions to fungal species. Fungal Diversity 72: 1 - 197. https: // doi. org / 10.1007 / s 13225 - 015 - 0324 - y","Barr, M. E. (1990) Melanommatales (Loculoascomycetes). In: North American Flora. Series (II). New York Botanical Garden, New York, 129 pp.","Tian, Q., Liu, J. K., Hyde, K. D., Wanasinghe, D. N., Boonmee, S., Jayasiri, S. C., Luo, Z. L., Taylor, J. E., Phillips, A. J. L., Bhat, D. J., Li, W. J., Ariyawansa, H., Thambugala, K. M., Jones, E. B. G., Chomnunti, P., Bahkali, A. H., Xu, J. C. & Camporesi, E. (2015) Phylogenetic relationships and morphological reappraisal of Melanommataceae (Pleosporales). Fungal Diversity 74: 267 - 324. https: // doi. org / 10.1007 / s 13225 - 015 - 0350 - 9","Samuels, G. J. & Muller, E. (1978) Life-history studies of Brazilian ascomycetes 4. Three species of Herpotricia and their pyrenochaetalike anamorphs. Sydowia 31: 157 - 168.","Jayasiri, S. C., Hyde, K. D., Jones, E. B. G., Mckenzie, E., Jeewon, R., Phillips, A. J. L., Bhat, D. J., Wanasinghe, D. N., Liu, J. K., Lu, Y. Z., Kang, J. C., Xu, J. & Karunarathna, S. C. (2019) Diversity, morphology and molecular phylogeny of Dothideomycetes on decaying wild seed pods and fruits. Mycosphere 10 (1): 1 - 186. https: // doi. org / 10.5943 / mycosphere / 10 / 1 / 1","Tanaka, K., Hirayama, K., Yonezawa, H. & Sato, G. (2015) Revision of the Massarineae (Pleosporales, Dothideomycetes). Studies in Mycology 82: 75 - 36. https: // doi. org / 10.1016 / j. simyco. 2015.10.002","Phukhamsakda, C., McKenzie, E. H. C., Phillips, A. J. L., Jones, E. B. G., Bhat, D. J., Stadler, M., Bhunjun, C. S., Wanasinghe, D. N., Thongbai, B., Camporesi, E., Ertz, D., Jayawardena, R. S., Perera, R. H., Ekanayake, A. H., Tibpromma, S., Doilom, M., Xu, J. C. & Hyde, K. D. (2020) Microfungi associated with Clematis (Ranunculaceae) with an integrated approach to delimiting species boundaries. Fungal Diversity 102: 1 - 203. https: // doi. org / 10.1007 / s 13225 - 020 - 00448 - 4","Hyde, K. D., Hongsanan, S., Jeewon, R., Bhat, D. J., McKenzie, E. H. C., Jones, E. B. G., Phookamsak, R., Ariyawansa, H. A., Boonmee, S., Zhao, Q., Abdel-Aziz, F. A., Abdel-Wahab, M. A., Banmai, S., Chomnunti, P., Cui, B. K., Daranagama, D. A., Das, K., Dayarathne, M. C., de Silva, N. I., Dissanayake, A. J., Doilom, M., Ekanayaka, A. H., Baptista, G. T., Goes-Neto, A., Huang, SK., Jayasiri, S. C., Jayawardena, R. S., Konta, S., Lee, H. B., Li, W. J., Lin, C. G., Liu, J. K., Lu, Y. Z., Luo, Z. L., Manawasinghe, I. S., Manimohan, P., Mapook, A., Niskanen, T., Norphanphoun, C., Papizadeh, M., Perera, R. H., Phukhamsakda, C., Richter, C., de A. Santiago, A. L. C. M., Drechsler-Santos, E. R., Senanayake, I. C., Tanaka, K., Tennakoon, D. S., Thambugala, K. M., Tian, Q., Tibpromma, S., Thongbai, B., Vizzini, A., Wanasinghe, D. N., Wijayawardene, N. N., Wu, HX., Yang, J., Zeng, X. Y., Zhang, H., Zhang, J. F., Bulgakov, T. S., Camporesi, E., Bahkali, A. H., Amoozegar, M. A., Araujo-Neta, L. S., Ammirati, J. F., Baghela, A., Bhatt, R. P., Bojantchev, D., Buyck, B., da Silva, G. A., de Lima, C. L. F., de Oliveira, R. J. V., de Souza, C. A. F., Dai, Y. C., Dima, B., Duong, T. T., Ercole, E., Mafalda-Freire, F., Ghosh, A., Hashimoto, A., Kamolhan, S., Kang, J. C., Karunarathna, S. C., Kirk, P. M., Kytovuori, I., Lantieri, A., Liimatainen, K., Liu, Z. Y., Liu, X. Z., Lucking, R., Medardi, G., Mortimer, P. E., Nguyen, T. T. T., Promputtha, I., Anil Raj, K. N., Reck, M. A., Lumyong, S., Shahzadeh-Fazeli, S. A., Stadler, M., Soudi, M. R., Su, H. Y., Takahashi, T., Tangthirasunun, N., Uniyal, P., Wang, Y., Wen, T. C., Xu, J. C., Zhang, Z. K., Zhao, Y. C., Zhou, J. L. & Zhu, L. (2016) Fungal diversity notes 367 - 500: taxonomic and phylogenetic contributions to fungal taxa. Fungal Diversity 80: 1 - 270. https: // doi. org / 10.1007 / s 13225 - 016 - 0373 - x","Tennakoon, D. S., Bhat, D. J., Chang-Hsin, K. & Hyde, K. D. (2019) Leaf litter saprobic Dictyosporiaceae (Pleosporales, Dothideomycetes): Pseudocoleophoma zingiberacearum sp. nov. from Hedychium coronarium. Kavaka 53: 1 - 67. https: // doi. org / 10.36460 / Kavaka / 53 / 2019 / 1 - 7"]}

Published

2022

12. Microfungi associated with ornamental palms: Byssosphaeria phoenicis sp. nov. (Melanommataceae) and Pseudocoleophoma rhapidis sp. nov. (Dictyosporiaceae) from south China

Author

KULARATHNAGE, NUWAN D., primary, WANASINGHE, DHANUSHKA N., additional, SENANAYAKE, INDUNIL C., additional, YANG, YUNHUI, additional, MANAWASINGHE, ISHARA S., additional, PHILLIPS, ALAN J.L., additional, HYDE, KEVIN D., additional, DONG, WEI, additional, and SONG, JIAGE, additional

Published

2022

13. THE CHROMOSOME ERRORS OF HUMAN BLASTOCYST IN AGE OF 44 YEARS OLD AND BEYOND

Author

Liu, Hui, primary, Song, Jiage, additional, and Zhang, John J., additional

Published

2022

14. High-performance and low-cost organic solar cells based on pentacyclic A–DA′D–A acceptors with efficiency over 16%

Author

Xu, Xiang, primary, Wei, Qingya, additional, Song, Jiage, additional, Jing, Jianhua, additional, Chen, Yanwei, additional, Huang, Fei, additional, Lu, Xinhui, additional, Zhou, Yonghua, additional, Yuan, Jun, additional, and Zou, Yingping, additional

Published

2022

15. Regulating the properties of small molecular acceptors with different end groups

Author

Li, Jing, Song, Jiage, Chen, Honggang, Wei, Qingya, Yuan, Jun, Peng, Hongjian, and Zou, Yingping

Published

2021

16. Over 13% Efficient Organic Solar Cells Based on Low‐Cost Pentacyclic A‐DA′D‐A‐Type Nonfullerene Acceptor

Author

Song, Jiage, primary, Cai, Fangfang, additional, Zhu, Can, additional, Chen, Honggang, additional, Wei, Qingya, additional, Li, Dongxu, additional, Zhang, Chujun, additional, Zhang, Rui, additional, Yuan, Jun, additional, Peng, Hongjian, additional, So, Shu Kong, additional, and Zou, Yingping, additional

Published

2021

17. Correlating the Molecular Structure of A‐DA′D‐A Type Non‐Fullerene Acceptors to Its Heat Transfer and Charge Transport Properties in Organic Solar Cells

Author

Zhang, Chujun, primary, Yuan, Jun, additional, Ho, Johnny Ka Wai, additional, Song, Jiage, additional, Zhong, Hui, additional, Xiao, Yiqun, additional, Liu, Wei, additional, Lu, Xinhui, additional, Zou, Yingping, additional, and So, Shu Kong, additional

Published

2021

18. Over 13% Efficient Organic Solar Cells Based on Low-Cost Pentacyclic A-DA D-A-Type Nonfullerene Acceptor

Author

Song, Jiage, Cai, Fangfang, Zhu, Can, Chen, Honggang, Wei, Qingya, Li, Dongxu, Zhang, Chujun, Zhang, Rui, Yuan, Jun, Peng, Hongjian, So, Shu Kong, Zou, Yingping, Song, Jiage, Cai, Fangfang, Zhu, Can, Chen, Honggang, Wei, Qingya, Li, Dongxu, Zhang, Chujun, Zhang, Rui, Yuan, Jun, Peng, Hongjian, So, Shu Kong, and Zou, Yingping

Abstract

Recent studies have almost focused on finding active layer materials with extended pi-conjugation structures for high-performance organic solar cells (OSCs). However, with the extension of conjugate length, the synthesis difficulty and cost of materials will increase. Achieving high efficiency while reducing material costs is a prerequisite for the commercialization of OSCs. Herein, two low-cost A-DA D-A-type (where A and D represent an electron-withdrawing unit and an electron-donating unit, respectively) nonfullerene acceptors (Y25,Y26) are synthesized with pentacyclic fused backbone as the DA D electron-deficient core and 5,6-difluoro-3-(dicyandiamethyl) indigo as the end groups. Compared with classical Y series acceptors with heptacyclic backbone, although Y25 and Y26 own the reduced conjugated length, they still show moderate performance (11.65% and 13.34%), and the cost of synthesis is significantly reduced. Therefore, we provide a new molecular design idea for commercially efficient nonfullerene OSCs acceptors. We also find that adding alkyl chains to the beta site of thiophenes is beneficial to obtaining the reduced energetic disorder, dominant molecular stacking, and desirable morphology, which can facilitate charge carrier transport and prompt higher short-circuit current density (J(sc)) as well as fill factor., Funding Agencies|National Natural Science Foundation of ChinaNational Natural Science Foundation of China (NSFC) [21875286]; Hunan Intellectual Property Bureau [2016e004]; Science and Technology Plan Key Project of Hunan Province [2020GK2100]; Natural Science Foundation of Hunan ProvinceNatural Science Foundation of Hunan Province [2020JJ4721]

Published

2021

19. Puccinia xinyuanensis sp. nov., the causal agent of rust on wild tulip (Tulipa iliensis) in China

Author

SONG, JIAGE, primary, AIME, MARY CATHERINE, additional, and XU, BIAO, additional

Published

2020

20. A rare exonic NRXN3 deletion segregating with neurodevelopmental and neuropsychiatric conditions in a three-generation Chinese family

Author

Yuan, Haiming, primary, Wang, Qingming, additional, Liu, Yanhui, additional, Yang, Wei, additional, He, Yi, additional, Gusella, James F., additional, Song, Jiage, additional, and Shen, Yiping, additional

Published

2018

21. Powdery mildew caused by Erysiphe lespedezae (including Pseudoidium caesalpiniacearum, syn. nov.) on Bauhinia blakeana and B. purpurea in China

Author

XU, BIAO, primary, BRAUN, UWE, additional, ZHANG, SHANHE, additional, YANG, HUI, additional, CAO, ZHI, additional, GUO, YAXU, additional, and SONG, JIAGE, additional

Published

2018

22. A Destructive Leaf Spot and Blight Caused by Alternaria kareliniae sp. nov. on a Sand-Stabilizing Plant, Caspian Sea Karelinia

Author

Xu, Biao, primary, Song, Jiage, additional, Xi, Pinggen, additional, Li, Minhui, additional, Hsiang, Tom, additional, and Jiang, Zide, additional

Published

2018

23. Comparative Researches of Semen Arecae and Charred Semen Arecae on Gastrointestinal Motility, Motilin, Substance P, and CCK in Chronically Stressed Rats

Author

Zhang, Sanyin, primary, Yang, Peng, additional, Li, Xixiong, additional, Wang, Xin, additional, Song, Jiage, additional, Peng, Wei, additional, and Wu, Chunjie, additional

Published

2017

24. Pustula junggarensis (Albuginales, Oomycota), a new species of white blister rust on Takhtajaniantha pusilla from Junggar Basin in China

Author

XU, BIAO, primary, SONG, JIAGE GE, additional, XI, PING GEN, additional, and JIANG, ZI DE, additional

Published

2016

25. A rare exonic NRXN3deletion segregating with neurodevelopmental and neuropsychiatric conditions in a three‐generation Chinese family

Author

Yuan, Haiming, Wang, Qingming, Liu, Yanhui, Yang, Wei, He, Yi, Gusella, James F., Song, Jiage, and Shen, Yiping

Abstract

Members of the neurexin gene family, neurexin 1 (NRXN1), neurexin 2 (NRXN2), and neurexin 3 (NRXN3) encode important components of synaptic function implicated in autism and other neurodevelopmental/neuropsychiatric disorders. Loss of function variants have been reported predominantly in NRXN1, with fewer such variants detected in NRXN2and NRXN3. Evidence for segregating NRNX3variants has particularly been lacking. Here, we report identification by chromosomal microarray analysis of a rare exonic deletion affecting the NRXN3alpha isoform in a three‐generation Chinese family. The proband, a 7‐year‐old boy, presented with motor and language delay and met the clinical diagnostic criteria for autism. He also presented with moderate intellectual disability, attention‐deficit hyperactivity disorder and facial dysmorphic features. The mother and maternal grandfather, both deletion carriers, presented with variable degrees of language and communication difficulties, as well as neuropsychiatric problems such as schizophrenia and temper tantrums. A compilation of sporadic cases with deletions involving part or all of NRXN3revealed that 9 of 23 individuals (39%) displayed features of autism. The evidence for cosegregation in our family further supports a role for NRXN3in autism and neurodevelopmental/neuropsychiatric disorders but demonstrates intrafamily variable expressivity due to this NRXN3deletion, with schizophrenia and facial dysmorphism being potential novel features of NRXN3haploinsufficiency.

Published

2018

26. Catalogue of fungi in China 4: Didymiaceae and Physaraceae (Myxomycetes).

Author

Li, Xuefei, Hu, Jiajun, Tuo, Yonglan, Li, You, Dai, Dan, Sossah, Frederick Leo, Liu, Minghao, Wang, Jiajia, Song, Jiage, Zhang, Bo, Li, Xiao, and Li, Yu

Subjects

*MYXOMYCETES, *SPECIES diversity, *SPECIES, *TAXONOMY, *CATALOGS

Abstract

Myxomycetes play crucial ecological roles, yet their species diversity, distribution, and taxonomic relationships remain poorly understood. In this study, we examined 104 specimens from 19 provinces in China. Through morphological analysis, we identified a group of species with reduced lime formation, a feature typically associated with the Physaraceae, but with key morphological similarities to the Diderma. A comprehensive phylogenetic analysis was conducted using three genes (nSSU, EF-1α, and COI), resulting in a dataset of 452 sequences from 116 species. Notably, we identified a distinct clade within Didymiaceae containing species with fewer lime knots, a trait traditionally linked to Physaraceae. This clade, designated as the new genus Neodiderma, was phylogenetically positioned as a sister group to Diderma, potentially representing a transitional group between Didymiaceae and Physaraceae, supported by both morphological and molecular evidence. Eleven new species — N. macrosporum, N. pseudobisporum, N. verrucocapillitium, N. rigidocapillitium, N. rufum, Physarum guangxiense, P. subviride, P. nigritum, P. biyangense, P. neoovoideum, and P. jilinense — were identified from China, and their phylogenetic positions were analysed. Additionally, N. spumarioides (formerly Diderma spumarioides) was recombined. The new and recombined species were formally described and illustrated, and a key to the sections and species of Neodiderma and Physarum was provided. [ABSTRACT FROM AUTHOR]

Published

2024