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1. Numerical study of high-energy spark ignition characteristics in a scramjet combustor

Author

Ziyan Gao, Meng Zhang, Zhibo Zhang, Yun Wu, Xing Zheng, and Huifeng Miao

Subjects
Ignition, Scramjet engine, Supersonic combustion, High-energy spark, Engineering (General). Civil engineering (General), TA1-2040
Abstract

Reliable ignition is a fundamental prerequisite for the scramjet engines. In order to improve the reliability of ignition, further enhance the application of spark ignition in engineering, and improve the ignition ability in the field of supersonic combustion, an innovative long electrode distance high-energy spark igniter (LHSI) system was proposed by our research team. To reveal the instantaneous ignition characteristics of the LHSI, a simulation model of the LHSI is established and verified by experiments. Based on this, the formation and development of the initial flame kernel of vaporized kerosene and the ignition characteristics of LHSI in a scramjet combustor were simulated and compared with the conventional high-energy spark igniter (HSI). The analysis revealed that the success of the cavity ignition is greatly influenced by the local equivalent ratio of the initial flow field and the penetration depth of the initial flame kernel. Meanwhile, the fore recirculation zone of the cavity plays a key role in stabilization and development of the initial flame kernel. Compared with the HSI, the LHSI can produce initial flame kernel with higher penetration and greater size, which is the main reason why LHSI has a broader ignition boundary. The simulation results show that the oil-rich and oil-lean ignition boundaries of LHSI are about 17 % and 55 % wider than those of HSI, respectively.

Published
2024
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2. Tracking tantalum stocks and flows in China from 2000 to 2021: A material flow analysis

Author

Zhen Gao, Yong Geng, Ziyan Gao, Zhou Liang, and Wendong Wei

Subjects
Tantalum, Material flow analysis, China, Recycling, Electronics, Conflict mineral, Science (General), Q1-390, Social sciences (General), H1-99
Abstract

Tantalum is not only one of the critical metals applied in various advanced industries such as electronics, aerospace, military, and medical applications, but also is considered a conflict mineral, posing a threat to its global supply security. China plays a significant role in the tantalum industrial chain; however, the complete picture of its anthropogenic tantalum cycle remains unknown. This study investigates the tantalum cycles in China from 2000 to 2021 by conducting a dynamic material flow analysis. The results reveal that China's domestic tantalum consumption surged from 91 tons in 2000 to 580 tons in 2021. China heavily relied on importing tantalum minerals to support its domestic production, with a trade dependence rate of 90 %. Moreover, the trade volume of tantalum-related commodities experienced substantial growth from 2000 to 2014 and then fluctuated, with tantalum concentrates as the primary imported goods and electronic products as the primary exported goods. Approximately 24.9 % of the overall tantalum demand was met with secondary tantalum, in which 80 % of such secondary material being recovered during the refining and production stages. Policy recommendations are proposed accordingly, including diversifying tantalum mineral resources and increasing the recovery rates from end-of-life products. These policies can significantly contribute to achieving sufficient tantalum supply and maintaining sustainable tantalum supply chain in China.

Published
2024
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3. VMP1: a multifaceted regulator of cellular homeostasis with implications in disease pathology

Author

Jia Tong, Qianqian Wang, Ziyan Gao, Yang Liu, and Chengbiao Lu

Subjects
VMP1, autophagy, lipid scramblases, ER stress, coronavirus, Biology (General), QH301-705.5
Abstract

Vacuole membrane protein 1 (VMP1) is an integral membrane protein that plays a pivotal role in cellular processes, particularly in the regulation of autophagy. Autophagy, a self-degradative mechanism, is essential for maintaining cellular homeostasis by degradation and recycling damaged organelles and proteins. VMP1 involved in the autophagic processes include the formation of autophagosomes and the subsequent fusion with lysosomes. Moreover, VMP1 modulates endoplasmic reticulum (ER) calcium levels, which is significant for various cellular functions, including protein folding and cellular signaling. Recent studies have also linked VMP1 to the cellular response against viral infections and lipid droplet (LD). Dysregulation of VMP1 has been observed in several pathological conditions, including neurodegenerative diseases such as Parkinson’s disease (PD), pancreatitis, hepatitis, and tumorogenesis, underscoring its potential as a therapeutic target. This review aims to provide an overview of VMP1’s multifaceted roles and its implications in disease pathology.

Published
2024
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4. Mapping the evolution of manganese flows and stocks in China from 2000 to 2021

Author

Enyan Zhu, Yong Geng, Shijiang Xiao, Tianjiao Guo, Ziyan Gao, and Zhen Gao

Subjects
Manganese, Dynamic material flow analysis, Evolution, Supply and demand, Environmental sciences, GE1-350, Environmental effects of industries and plants, TD194-195
Abstract

Manganese is a strategic metal that has been widely applied in the steelmaking industry and the emerging energy batteries industry. China is the largest manganese importer and consumer, but the critical features of its manganese metabolisms, including its supply and demand, trade, and waste management, remain unclear. By applying dynamic material flow analysis (DMFA) method, this research investigates the evolution of China’s anthropogenic manganese flows and stocks during the period of 2000 to 2021. We found that the demand for manganese had increased almost tenfold in China from 2000 to 2021, mainly used for steelmaking, while the surging demand for manganese in energy batteries had gradually increased. However, China highly relied on importing manganese concentrates due to its limited manganese resources. The cumulative in-use manganese stocks also increased by tenfold and reached approximately 168 million tons (Mt). In addition, manganese flow from the end-of-life (EoL) final products reached 12 Mt in 2021, but few of them were recycled, implying a huge recycling potential. These findings provide valuable insights to prepare more appropriate manganese resource management policies, such as improving domestic mining technologies, enhancing manganese recycling, and diversifying the supply of manganese resources, so that the overall manganese resource efficiency can be improved.

Published
2024
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5. Deformation prediction of the Northern Mountain landslide in Lijie Town of Zhouqu, Gansu Province based on long-short term memory network

Author

Ziyan GAO, Ruidong LI, Pengqing SHI, Xiaolong ZHOU, and Juan ZHANG

Subjects
landslide, lstm neural network, predictive analysis, north mountain of lijie, machine learning, Geology, QE1-996.5
Abstract

The North Mountain landslide in Lijie Town has been in a long-term creeping deformation state and has experienced multiple landslide and debris flow disasters. Monitoring the surface deformation of landslide to grasp the surface deformation pattern of disaster body is a reliable basis for realizing early warning prediction of geological disaster. In this paper, a machine learning model is introduced to predict the relevant data, and a long and short-term memory network is used to predict the landslide deformation by monitoring the displacement data of North Mountain in Lijie, and the prediction results are compared with the actual data and analyzed. In this paper, root mean square error , mean absolute error , coefficient of determination and explainable variance are used to evaluate the prediction results, among which the coefficient of determination and explainable variance reach 0.99. It shows that the long short-term memory network used in this paper achieves good prediction performance in the prediction of landslide deformation in the North Mountain of Lijie.

Published
2023
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6. The Application of Remote Sensing Technology in Post-Disaster Emergency Investigations of Debris Flows: A Case Study of the Shuimo Catchment in the Bailong River, China

Author

Feibiao Huo, Fuyun Guo, Pengqing Shi, Ziyan Gao, Yan Zhao, Yongbin Wang, Xingmin Meng, and Dongxia Yue

Subjects
debris flow, remote sensing, formation mechanism, emergency investigation, Science
Abstract

The Bailongjiang River Basin is a high-risk area for debris flow in China. On 17 August 2020, a debris flow occurred in the Shuimo catchment, Wen County, which blocked the Baishui River, forming a barrier lake and causing significant casualties and property damage. In this study, remote sensing, InSAR, field surveys, and unmanned aerial vehicle (UAV) techniques were used to analyze the causal characteristics, material source characteristics, dynamic processes, and disaster characteristics after the debris flow. The results showed that the Shuimo catchment belongs to low-frequency debris flows, with a recurrence cycle of more than 100 years and concealed features. High vegetation coverage (72%) and a long main channel (11.49 km) increase the rainfall-triggering conditions for debris flow occurrence, making it more hidden and less noticed. The Shuimo catchment has a large drainage area of 31.26 km2, 15 tributaries, significant elevation differences of 2017 m, and favorable hydraulic conditions for debris flow. The main sources of debris flow material supply are channel erosion and slope erosion, which account for 84.4% of the total material. The collapse of landslides blocking both sides of the main channel resulted in an amplification of the debris flow scale, leading to the blockage of the Baishui River. The scale of the accumulation fan is 28 × 104 m3, and the barrier lake area is 37.4 × 104 m2. The formation mechanism can be summarized as follows: rainfall triggering → shallow landslides → slope debris flow → channel erosion → landslide damming → dam failure and increased discharge → deposition and river blockage. The results of this study provide references for remote sensing emergency investigation and analysis of similar low-frequency and concealed debris flows, as well as a scientific basis for local disaster prevention and reduction.

Published
2024
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7. Biomimetic Electronic Skin through Hierarchical Polymer Structural Design

Author

Mengnan Zhang, Shu Gong, Karen Hakobyan, Ziyan Gao, Zeyu Shao, Shuhua Peng, Shuying Wu, Xiaojing Hao, Zhen Jiang, Edgar H. Wong, Kang Liang, Chun H. Wang, Wenlong Cheng, and Jiangtao Xu

Subjects
artificial skin, electronic skin, hydrogel, interfacial precipitation polymerization, polymer nanoparticles, triboelectric nanogenerator, Science
Abstract

Abstract Human skin comprises multiple hierarchical layers that perform various functions such as protection, sensing, and structural support. Developing electronic skin (E‐skin) with similar properties has broad implications in health monitoring, prosthetics, and soft robotics. While previous efforts have predominantly concentrated on sensory capabilities, this study introduces a hierarchical polymer system that not only structurally resembles the epidermis‐dermis bilayer structure of skin but also encompasses sensing functions. The system comprises a polymeric hydrogel, representing the “dermis”, and a superimposed nanoporous polymer film, forming the “epidermis”. Within the film, interconnected nanoparticles mimic the arrangement of interlocked corneocytes within the epidermis. The fabrication process employs a robust in situ interfacial precipitation polymerization of specific water‐soluble monomers that become insoluble during polymerization. This process yields a hybrid layer establishing a durable interface between the film and hydrogel. Beyond the structural mimicry, this hierarchical structure offers functionalities resembling human skin, which includes (1) water loss protection of hydrogel by tailoring the hydrophobicity of the upper polymer film; (2) tactile sensing capability via self‐powered triboelectric nanogenerators; (3) built‐in gold nanowire‐based resistive sensor toward temperature and pressure sensing. This hierarchical polymeric approach represents a potent strategy to replicate both the structure and functions of human skin in synthetic designs.

Published
2024
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8. Stress compensation based on interfacial nanostructures for stable perovskite solar cells

Author

Cheng Zhu, Xi Wang, Hangxuan Li, Chenyue Wang, Ziyan Gao, Pengxiang Zhang, Xiuxiu Niu, Nengxu Li, Zipeng Xu, Zhenhuang Su, Yihua Chen, Huachao Zai, Haipeng Xie, Yizhou Zhao, Ning Yang, Guilin Liu, Xueyun Wang, Huanping Zhou, Jiawang Hong, Xingyu Gao, Yang Bai, and Qi Chen

Subjects
interfacial nanostructures, long‐term stability, perovskite solar cells, strain engineering, thermal expansion coefficient, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Abstract The long‐term stability issue of halide perovskite solar cells hinders their commercialization. The residual stress–strain affects device stability, which is derived from the mismatched thermophysical and mechanical properties between adjacent layers. In this work, we introduced the Rb2CO3 layer at the interface of SnO2/perovskite with the hierarchy morphology of snowflake‐like microislands and dendritic nanostructures. With a suitable thermal expansion coefficient, the Rb2CO3 layer benefits the interfacial stress relaxation and results in a compressive stress–strain in the perovskite layer. Moreover, reduced nonradiative recombination losses and optimized band alignment were achieved. An enhancement of open‐circuit voltage from 1.087 to 1.153 V in the resultant device was witnessed, which led to power conversion efficiency (PCE) of 22.7% (active area of 0.08313 cm2) and 20.6% (1 cm2). Moreover, these devices retained 95% of its initial PCE under the maximum power point tracking (MPPT) after 2700 h. It suggests inorganic materials with high thermal expansion coefficients and specific nanostructures are promising candidates to optimize interfacial mechanics, which improves the operational stability of perovskite cells.

Published
2023
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9. Stable large-area monodomain in as-grown bulk ferroelectric single crystal Sn2P2S6

Author

Yingzhuo Lun, Jiaqian Kang, Wenfu Zhu, Jianming Deng, Xingan Jiang, Cheng Zhu, Qi Ren, Xian Zi, Ziyan Gao, Tianlong Xia, Zishuo Yao, Xueyun Wang, and Jiawang Hong

Subjects
monodomain, ferroelectricity, piezoelectric force microscopy, disproportionation reaction, charge carriers, Electricity, QC501-721
Abstract

Driven by the minimization of total energy, the multi-domain morphology is preferred in as-grown ferroelectrics to reduce the depolarization and strain energy during the paraelectric to ferroelectric phase transition. However, the complicated multi-domain is not desirable for certain high-performance ferroelectric electro-optic devices. In this work, we achieve a reproducible and stable large-area monodomain in as-grown bulk ferroelectric single crystal [Formula: see text]. The monodomain dominates the entire single crystal, which is attributed to the internal charge carriers from the photoexcited disproportionation reaction of Sn ions. The charge carriers effectively screen the depolarization field and therefore decrease the depolarization energy and facilitate the formation of monodomain. This work offers a potential approach for engineering bulk ferroelectrics with a stable monodomain, which is desirable for the high-performance ferroelectric electro-optic devices.

Published
2023
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10. Ventrolateral Periaqueductal Gray Neurons Are Active During Urination

Author

Yu Rao, Ziyan Gao, Xianping Li, Xing Li, Jun Li, Shanshan Liang, Daihan Li, Jinliang Zhai, Junan Yan, Jiwei Yao, and Xiaowei Chen

Subjects
fiber photometry, pontine micturition center, ventrolateral periaqueductal gray (vlPAG), urination, cystometry, rabies virus, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

The ventrolateral periaqueductal gray (VLPAG) is thought to be the main PAG column for bladder control. PAG neurons (especially VLPAG neurons) and neurons in the pontine micturition center (PMC) innervating the bladder detrusor have anatomical and functional synaptic connections. The prevailing viewpoint on neural control of the bladder is that PAG neurons receive information on the decision to void made by upstream brain regions, and consequently activate the PMC through their direct projections to initiate urination reflex. However, the exact location of the PMC-projecting VLPAG neurons, their activity in response to urination, and their whole-brain inputs remain unclear. Here, we identified the distribution of VLPAG neurons that may participate in control of the bladder or project to the PMC through retrograde neural tracing. Population Ca2+ signals of PMC-projecting VLPAG neurons highly correlated with bladder contractions and urination as shown by in vivo recording in freely moving animals. Using a RV-based retrograde trans-synaptic tracing strategy, morphological results showed that urination-related PMC-projecting VLPAG neurons received dense inputs from multiple urination-related higher brain areas, such as the medial preoptic area, medial prefrontal cortex, and lateral hypothalamus. Thus, our findings reveal a novel insight into the VLPAG for control of bladder function and provide a potential therapeutic midbrain node for neurogenic bladder dysfunction.

Published
2022
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11. Mapping the global flows of steel scraps: an alloy elements recovery perspective

Author

Wenqiu Cai, Yong Geng, Meng Li, Ziyan Gao, and Wendong Wei

Subjects
steel scraps, social network analysis, alloy elements, material flow analysis, governance, resource management, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999
Abstract

Recycling steel scraps by the use of electric arc furnace is one of the most promising approaches for the steel industry to achieve net-zero emissions. Due to the uneven distribution of global steel scraps, many countries are actively involving in the global steel scraps trade. Steel scraps contain a range of critical elements, which may be transferred across borders through international trade of steel scraps. However, existing studies have paid little attention to the global flows of steel scraps and its embodied alloy elements (AEs). This study maps the journey of global steel scraps and the embodied AEs for the period of 2000–2021 for the first time by employing trade-linked material flow analysis and social network analysis. The results indicate that the global steel scraps trade had increased during the study period, with a few core countries (such as USA, Germany, and Turkey) leading the global steel scraps network. Also, critical metals had been transferred across borders in the form of AEs through the trade of steel scraps, especially from global north countries to global south countries. The largest AE flows include Chromium (Cr), nickel (Ni), manganese (Mn) and molybdenum (Mo) flows. Other AE flows, such as cobalt (Co), vanadium (V), and niobium (Nb) flows, were less, but with high values or being regarded scarce. From a global perspective, steel scraps trade and recycling can contribute to the decarbonization efforts of the global steel industry and address resource shortages in some countries. Therefore, it is urgent to promote the overall resource efficiency of steel scraps and the embodied AEs by various efforts.

Published
2023
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12. Analysis of the Gravity Movement and Decoupling State of China’s CO2 Emission Embodied in Fixed Capital Formation

Author

Xi Zhang, Ziyan Gao, Yong Geng, Yen Wah Tong, Harn Wei Kua, Xiaoqian Song, Yue Xu, and Fei Wu

Subjects
CO2 emissions, fixed capital formation, gravity movement, decoupling state, China, Technology
Abstract

Investment is an essential engine of economic growth and a major source of China’s CO2 emission. It is therefore crucial to explore the gravity movement and decoupling state of China’s CO2 emission embodied in fixed capital formation (FCF). This study aims to estimate China’s CO2 emissions embodied in various categories of FCF by using input–output tables. The gravity model and Shapley decomposition method are used to explore the gravity movement and regional contributions for China’s CO2 emissions embodied in FCF. Then, the Tapio decoupling model and logarithmic mean Divisia index (LMDI) method are combined to uncover the decoupling relationship between CO2 emissions and economic growth embodied in FCF and the corresponding driving factors. The results show that China’s CO2 emissions embodied in FCF experienced a rapid increase during 2002–2012 and remained almost stable during 2012–2017. The gravity center for CO2 emissions embodied in FCF moved toward northwest during 2002–2015, with the northwestern region and middle Yellow River region being the main engine regions. The relations between CO2 emissions and added values embodied in various categories of FCF were weak decoupling during 2002–2017. Investment scale was the major factor inhibiting the decoupling, while embodied energy intensity was the major factor promoting the decoupling. Finally, several policy recommendations are proposed based on these findings.

Published
2020
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23. Mechanical manipulation for ordered topological defects.

Author

Ziyan Gao, Yixuan Zhang, Xiaomei Li, Xiangping Zhang, Xue Chen, Guoshuai Du, Fei Hou, Baijun Gu, Yingzhuo Lun, Yao Zhao, Yingtao Zhao, Zhaoliang Qu, Ke Jin, Xiaolei Wang, Yabin Chen, Zhanwei Liu, Houbing Huang, Peng Gao, Mostovoy, Maxim, and Jiawang Hong

Subjects
*SYMMETRIC domains, *CONDENSED matter, *SYMMETRY breaking, *NANOINDENTATION, *FERROELECTRIC crystals, *FERROMAGNETIC materials
Abstract

Randomly distributed topological defects created during the spontaneous symmetry breaking are the fingerprints to trace the evolution of symmetry, range of interaction, and order parameters in condensed matter systems. However, the effective mean to manipulate topological defects into ordered form is elusive due to the topological protection. Here, we establish a strategy to effectively align the topological domain networks in hexagonal manganites through a mechanical approach. It is found that the nanoindentation strain gives rise to a threefold Magnus-type force distribution, leading to a sixfold symmetric domain pattern by driving the vortex and antivortex in opposite directions. On the basis of this rationale, sizeable mono-chirality topological stripe is readily achieved by expanding the nanoindentation to scratch, directly transferring the randomly distributed topological defects into an ordered form. This discovery provides a mechanical strategy to manipulate topological protected domains not only on ferroelectrics but also on ferromagnets/antiferromagnets and ferroelastics. [ABSTRACT FROM AUTHOR]

Published
2024
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24. Mapping the Global Anthropogenic Chromium Cycle: Implications for Resource Efficiency and Potential Supply Risk

Author

Ziyan Gao, Yong Geng, Shijiang Xiao, and Mufan Zhuang

Subjects
Chromium, Internationality, Metals, Metallurgy, Commerce, Environmental Chemistry, General Chemistry
Abstract

Chromium (Cr) is a critical metal due to its non-substitutable application in the metallurgy industry and highly uneven distribution of global reserve. However, there is a lack of in-depth analysis of global Cr flow patterns and its trade networks among individual cycles, which leaves the potential barriers and opportunities unexplored for improving chromium resource efficiency. Here, we employ a trade-linked multilevel material flow analysis (MFA) to map the global anthropogenic Cr cycle for year 2019. Social network analysis is also used to identify the key countries involved in the global Cr trade network. The results highlight that the global Cr cycle depends substantially on international trade in different forms, of which stainless steel is the leading application. Although South Africa, Kazakhstan, and Turkey are the major Cr primary resource suppliers, China and India play substantial roles in manufacturing Cr-containing products. Regional disparities exist in the scrap contents of individual country cycles, varying from 7% (uncertainty ranges from 4 to 11%) in China to 88% (uncertainty ranges from 87 to 89%) in India. Additionally, several countries are essential in the global Cr redistribution and in the connectivity of the Cr trade network, which may lead to their strong import dependence and even supply disruption.

Published
2022

25. A few-shot learning framework for planar pushing of unknown objects

Author

Armagan Elibol, ZIYAN GAO, and Nak Young Chong

Subjects
Non-prehensile Manipulation, Path Planning, Artificial Intelligence, Planar Pushing, Mechanical Engineering, Computational Mechanics, Data-driven Automation, Engineering (miscellaneous)
Abstract

Robot planar pushing is one of the primitive elements of non-prehensile manipulation skills, and has been widely studied as an alternative solution to complex manipulation tasks. To transfer this skill to novel objects, reasoning the pushing effect on object motion is important for selecting proper contact locations and pushing directions. However, complex contact conditions and unknown physical properties of the object cause difficulties in reasoning. In this work, firstly, we present a new large planar pushing dataset that contains a wide range of simulated objects, and a novel representation for pushing primitives for the data-driven prediction model. Secondly, we propose a computation efficient planning method that employs a heuristic to reduce the possibility of making sliding contact between the pusher and the object. The prediction model and planning method were evaluated both in simulation and real experimental settings. The results show that the prediction model purely trained using our simulation dataset is capable of predicting real object motions accurately. The push planning method effectively reduces the number of pushes required to move unknown real objects to target positions.

Published
2022

26. Zero Moment Two Edge Pushing of Novel Objects With Center of Mass Estimation

Author

Ziyan Gao, Armagan Elibol, and Nak Young Chong

Subjects
data-driven automation, Control and Systems Engineering, object CoM estimation, Electrical and Electronic Engineering, Planar pushing, two edge pushing
Abstract

Pushing is one of the fundamental nonprehensile manipulation skills to impart to an object changes in position and orientation. To exploit this skill to manipulate novel objects, explicit knowledge of their physical properties should be given a priori. In this work, we estimate the center of mass (CoM) of an object by narrowing down its probable location with a deep learning model and Mason’s voting theorem. In addition, we propose the Zero Moment Two Edge Pushing (ZMTEP) method to translate a novel object without rotation to a goal pose. The proposed method enables a pusher to select the most suitable two-edge-contact configuration for a given object using the estimated CoM and the geometrical shape of the object. Notably, neither the friction between the object and its support plane nor the friction between the object and the pusher are assumed to be known. We evaluate the proposed CoM estimation and ZMTEP methods through a series of experiments in both simulation and real robotic pusher settings. The result shows that the CoM estimation method has good mean squared error properties and small standard deviation, and the ZMTEP method significantly outperforms competitive baseline methods.

Published
2022

30. Evolution of the anthropogenic chromium cycle in China

Author

Chang Su, Xiaoqian Song, Yong Geng, Xianlai Zeng, Tianli Yao, Ziyan Gao, and Xu Tian

Subjects
Chromium, chemistry, Environmental protection, Material flow analysis, General Social Sciences, chemistry.chemical_element, Environmental science, Industrial ecology, China, General Environmental Science
Published
2021

33. Sandwiched electrode buffer for efficient and stable perovskite solar cells with dual back surface fields

Author

Haipeng Xie, Cheng Zhu, Yihua Chen, Pengxiang Zhang, Zijian Huang, Huachao Zai, Rundong Fan, Yang Bai, Yu Zhang, Jingjing Chang, Yujing Li, Xiao Zhang, Yue Ma, Xueyun Wang, Nengxu Li, Jiawang Hong, Kangwen Sun, Ziyan Gao, Sai Ma, Qi Chen, Huanping Zhou, and Jie Su

Subjects
General Energy, Materials science, Planar, Passivation, business.industry, Electrode, Optoelectronics, Perovskite solar cell, Thermal stability, business, Layer (electronics), Maximum power point tracking, Perovskite (structure)
Abstract

Summary With the rapid progress of perovskite solar cells (PSCs), both high efficiency and sufficient stability are required simultaneously for their real-life application, wherein interfaces play an essential role. In this work, we develop sandwiched electrode buffer (SEB) with respect to the hole-transport layer (HTL), wherein dual back surface fields are implemented at two interfaces in relevance. The SEB bridges the absorber to the back electrode with the desired band alignment and multi-defect passivation effects, which stabilize the perovskite, HTL, and metal electrodes. Accordingly, planar n-i-p PSCs with SEB achieve an efficiency of 23.9% (certified 23.4%). Notably, they exhibit a remarkable operational stability with only a 3% efficiency decline for 2,000 h maximum power point tracking under 1-Sun illumination. Furthermore, the devices also show excellent thermal stability and humidity stability. Therefore, the SEB configuration boosts both efficiency and stability of PSCs, which paves the way for the commercialization of perovskite optoelectronics.

Published
2021

34. Accounting greenhouse gas emissions of food consumption between urban and rural residents in China: a whole production perspective

Author

Shijiang Xiao, Yong Geng, Chenyi Zhang, Mufan Zhuang, Yanfeng Xu, and Ziyan Gao

Subjects
Consumption (economics), education.field_of_study, business.industry, Population, Energy Engineering and Power Technology, Agricultural economics, Agriculture, Urbanization, Greenhouse gas, Food processing, Production (economics), Environmental science, business, education, China
Abstract

Food consumption is necessary for human survival. On a global scale, the greenhouse gas (GHG) emission related to food consumption accounts for 19%–29% of the total GHG emission. China has the largest population in the world, which is experiencing a rapid development. Under the background of urbanization and the adjustment of the diet structure of Chinese residents, it is critical to mitigate the overall GHG emission caused by food consumption. This study aims to employ a singleregion input-output (SRIO) model and a multi-regional input-output (MRIO) model to measure GHG emission generated from food consumption in China and compare the contributions of different industrial sectors, uncovering the differences between urban and rural residents and among different provinces (autonomous regions/municipalities), as well as identifying the driving forces of GHG emission from food consumption at a national level. The results indicate that the total GHG emission generated from food consumption in China tripled from 157 Mt CO2e in 2002 to 452 Mt CO2e in 2017. The fastest growing GHG emission is from the consumption of other processed food and meat products. Although GHG emissions from both urban and rural residents increased, the gap between them is increasing. Agriculture, processing and manufacture of food, manufacture of chemical and transportation, storage and post services sectors are key sectors inducing food consumption related GHG emissions. From a regional perspective, the top five emission provinces (autonomous regions/municipalities) include Shandong, Hubei, Guangdong, Zhejiang, and Jiangsu. Based on such results, policy recommendations are proposed to mitigate the overall GHG emission from food consumption.

Published
2021

36. High-throughput Screening of Plastic Deformable Inorganic Semiconductors

Author

Jiawang Hong, Qi Ren, Yongheng Li, Ziyan Gao, Jianming Deng, Yingzhuo Lun, Xueyun Wang, and Gang Tang

Abstract

Inorganic semiconductors play an important role in fields such as information, sensor, and energy. But most bulk inorganic semiconductors are intrinsically brittle. With the development of smart electronic components like flexible electronic devices, it is urgent to explore plastically deformable inorganic semiconductors. For high-throughput screening of possible candidate materials, a reliable, universal, and convenient factor is needed. In this paper, a simple plastic deformability factor consisting of only elastic constants was proposed, which were examined by the experimentally verified plastic inorganic semiconductors Ag2S and InSe. Through data mining, 612 types of bulk layered materials were selected from more than 40,000 three-dimensional materials, two of which (PbI2 and CuInP2S6) were further experimentally verified, showing the reliability of this factor. This simple factor could be used to rapidly predict the plastic deformability of layered materials and large-scale screening of candidate inorganic materials for next-generation deformable and flexible electronic devices.

Published
2022

38. A snapshot of domain evolution between topological vortex and stripe in ferroelectric hexagonal ErMnO3

Author

Jiaqian Kang, Ziyan Gao, Changqing Guo, Wenfu Zhu, Houbing Huang, Jiawang Hong, Sang-Wook Cheong, and Xueyun Wang

Subjects
General Physics and Astronomy
Abstract

Hexagonal manganites exhibit three distinct domain patterns: stripe, loop, and vortex. Due to the high ferroelectric phase transition temperature and the lack of reliable visualization methods, it is still a mystery about the evolution and the formation of vortex networks. In this study, we managed to capture the coexistence of vortices, loops, and stripes by accurately controlling the annealing temperature right at Tc. We proposed a merging process between the V–AV pair and the stripe, which result in two different forms of vortex networks, namely, the normal vortex and the zigzag vortex. In addition, the connection between the density of stripes and the orientation of V–AV pairs is analyzed, which are both influenced by self-straining of the crystal. The mystery of evolution of the vortex network is unveiled by capturing the snapshot, and the experimental database provided calls for more analysis to understand the evolution of different domain topologies.

Published
2023

40. Uncovering CO2 emission drivers under regional industrial transfer in China’s Yangtze River Economic Belt: a multi-layer LMDI decomposition analysis

Author

Xu Tian, Xi Zhang, Ziyan Gao, Yong Geng, Wei Chen, and Huijuan Jiang

Subjects
Upstream (petroleum industry), business.industry, 020209 energy, Midstream, Energy Engineering and Power Technology, 02 engineering and technology, Divisia index, Heavy industry, 021001 nanoscience & nanotechnology, Environmental protection, Energy intensity, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0210 nano-technology, business, China, Downstream (petroleum industry), Efficient energy use
Abstract

With the relocation of heavy industries moving from downstream region to upstream and midstream regions in the Yangtze River Economic Belt (YREB), it is critical to encourage coordinated low carbon development in different regions within the YREB. This paper uncovers the evolution of CO2 emissions in different regions within the YREB for the period of 2000–2017. It decomposes regional CO2 emission changes using the temporal and cross-regional three-layer logarithmic mean Divisia index (LMDI) method. Besides, it decomposes industrial CO2 emission changes using the temporal two-layer LMDI method. The research results show that economic growth is the major driver for regional CO2 emission disparities. The mitigation drivers, such as energy intensity and energy structure, lead to a more decreased CO2 emission in the downstream region than in the upstream and midstream regions. In addition, it proposes several policy recommendations based upon the local realities, including improving energy efficiency, optimizing energy structure, promoting advanced technologies and equipment transfers, and coordinating the development in the upstream, midstream and downstream regions within the YREB.

Published
2020

41. Encapsulated X-Ray Detector Enabled by All-Inorganic Lead-Free Perovskite Film With High Sensitivity and Low Detection Limit

Author

Qixin Feng, Jiawang Hong, Xiangshun Geng, Xinran Zheng, Xichao Tan, Tian-Ling Ren, Mingyang Liu, Dan Xie, Hainan Zhang, Yi Yang, Rui Zhao, Min Chen, Yao Huang, Thomas Hirtz, Ziyan Gao, Ken Qin, Renrong Liang, Yuanyuan Zhou, He Tian, Nitin P. Padture, Guanhua Dun, Xue-Feng Wang, and Xueyun Wang

Subjects
Detection limit, Materials science, business.industry, Detector, X-ray detector, Carrier lifetime, Radiation, Electronic, Optical and Magnetic Materials, Optoelectronics, Electrical and Electronic Engineering, Dose rate, business, Inorganic lead, Solution process
Abstract

The sensitive detection of low-dose X-ray radiation is essential to many X-ray applications. In this article, the ultrasensitive X-ray detector based on pure Cs2AgBiBr6 all-inorganic lead-free perovskite film is successfully demonstrated and encapsulated using a metal casing with a Be window. The high-quality Cs2AgBiBr6 films are obtained through the low-cost solution process with long electron–hole diffusion length (~700 nm) and long carrier lifetime (~750 ns). Benefiting from the excellent properties of the Cs2AgBiBr6 film and the stable ambient provided by the packaging module, the resulting device exhibits attractive X-ray detection capabilities with a minimum detectable dose rate of 145.2 ${\mathrm {nGy}}_{air}\text{s}^{-1}$ and a detection sensitivity up to $1.8\times 10^{4}\,\,\mu {\mathrm {CGy}}_{air}{}^{-1}$ cm−2, which is about a thousand times higher than the sensitivity achieved with commercial a-Se X-ray detectors. Besides, the encapsulated device maintains superior detection performance after 2 months of storage, indicating the favorable reliability of the encapsulated device. This article demonstrates a possibility to use Cs2 AgBiBr6 perovskite film and Be window for the sensitive X-ray detection, which will inspire further development of radiation electronics by utilizing all-inorganic lead-free perovskite.

Published
2020

42. China’s CO2 emissions embodied in fixed capital formation and its spatial distribution

Author

Yong Geng, Ziyan Gao, Huijuan Jiang, Xi Zhang, Hengyu Pan, and Rui Wu

Subjects
Upstream (petroleum industry), Driving factors, Gross fixed capital formation, Natural resource economics, Input–output model, business.industry, Health, Toxicology and Mutagenesis, General Medicine, Divisia index, 010501 environmental sciences, Investment (macroeconomics), 01 natural sciences, Pollution, Supply and demand, Manufacturing, Environmental Chemistry, Environmental science, business, 0105 earth and related environmental sciences
Abstract

This study aims to measure China's CO2 emissions embodied in fixed capital formation (FCF) from 2007 to 2017 by using both a multi-regional input-output (MRIO) model and a single-region input-output model (SRIO). Then decoupling analysis was performed for uncovering the relationship between embodied CO2 emissions and added values at provincial level. Logarithmic Mean Divisia Index (LMDI) method was further conducted to identify driving factors underlying the growth of embodied CO2 emissions. Results show that CO2 emission from FCF doubled from 2436 million tons (Mt) in 2007 to 4820 Mt in 2012, and increased slightly to 5089 Mt in 2017. Electric power, gas, and water production and supply sector (EGW) and manufacturing industry (MFI) sector were two dominant emitters from supply-side perspective, while construction (CON) was the largest demanding sector driving the embodied emissions from upstream sectors. From geographical point of view, northern provinces were the major inter-regional net exporters of embodied CO2 emissions, while eastern and southern provinces were net importers of embodied CO2 emissions. Based on such results, policy recommendations are proposed considering the relation between supply and demand sector, inter-provincial CO2 emission transfer, and local economic development to mitigate CO2 emissions from China's FCF.

Published
2020

43. An in situ cross-linked 1D/3D perovskite heterostructure improves the stability of hybrid perovskite solar cells for over 3000 h operation

Author

Hao Wang, Jiawang Hong, Huachao Zai, Bin-Bin Cui, Yang Bai, Xi Wang, Xueyun Wang, Cheng Zhu, Chenyue Wang, Yihua Chen, Ning Yang, Qi Chen, Sai Ma, Huanping Zhou, and Ziyan Gao

Subjects
In situ, Materials science, Passivation, Maximum power principle, Renewable Energy, Sustainability and the Environment, business.industry, Energy conversion efficiency, Heterojunction, Tensile strain, Pollution, Nuclear Energy and Engineering, Environmental Chemistry, Optoelectronics, Grain boundary, business, Perovskite (structure)
Abstract

Long-term stability is an essential requirement for perovskite solar cells (PSCs) to be commercially viable. Heterojunctions built by low-dimensional and three-dimensional perovskites (1D/3D or 2D/3D) help to improve the stability of PSCs. However, the insulated organic cations of low-dimensional perovskite impede the transport of carriers, decreasing the power conversion efficiency (PCE) of PSCs. Herein, we introduce an in situ cross-linking polymerizable propargylammonium (PA+) to the 3D perovskite film at surfaces and grain boundaries to form a 1D/3D perovskite heterostructure. This passivation strategy not only significantly improves the interfacial carrier transport but also releases residual tensile strain in perovskite films. As a result, the corresponding devices achieve a champion PCE of 21.19%, while maintaining 93% of their initial efficiency after 3055 h of continuous illumination under maximum power point (MPP) operating conditions.

Published
2020

48. Association between

Author

Xueren, Gao, Jiaxin, Yang, Dongbo, Wang, Qinghang, Zeng, Fangting, Li, Sasha, Zhou, Xue, Zhang, Chen, Fan, Ziyan, Gao, and Yining, Zhao

Subjects
Carcinoma, Hepatocellular, Liver Neoplasms
Abstract

In recent years, several case-control studies have explored the association between the rs7763881 locus polymorphism of the

Published
2021

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