English | 繁體

Search in the results

UM

Browse/Search Results:  1-10 of 16 Help

Selected(0)Clear Items/Page:    Sort:
压力下超导 RbBSi 化合物的预测 Journal article
Liu, Jinyu, Cui, Xiangyue, Liu, Ailing, Cheng, Xiaoran, Wang, Xingyu, Wang, Yujia, Zhang, Miao. 压力下超导 RbBSi 化合物的预测[J]. Gaoya Wuli Xuebao/Chinese Journal of High Pressure Physics, 2024, 38(2), 020107.
Authors:  Liu, Jinyu;  Cui, Xiangyue;  Liu, Ailing;  Cheng, Xiaoran;  Wang, Xingyu; et al.
Favorite | TC[Scopus]:0 | Submit date:2024/06/05
Alkali-metal Boron-silicide  Crystal Structure Prediction  First-principles Calculations  High-pressure  
Enhanced sensitivity and linear-response in iontronic pressure sensors for non-contact, high-frequency vibration recognition Journal article
Su, Daojian, Shen, Gengzhe, Ma, Ke, Li, Junxian, Qin, Bolong, Wang, Shuangpeng, Yang, Weijia, He, Xin. Enhanced sensitivity and linear-response in iontronic pressure sensors for non-contact, high-frequency vibration recognition[J]. Journal of Colloid and Interface Science, 2024, 659, 1042-1051.
Authors:  Su, Daojian;  Shen, Gengzhe;  Ma, Ke;  Li, Junxian;  Qin, Bolong; et al.
Favorite | TC[WOS]:9 TC[Scopus]:9  IF:9.4/8.2 | Submit date:2024/05/02
Ag Nws/mxene Electrode  Highly Linear Sensitivity  Iontronic Pressure Sensors  Microstructure Design  Non-contact High-frequency Vibration Recognition  
Structural screening of phosphorus sulfur ternary hydride PSH6 with a high-temperature superconductivity at 130 GPa Journal article
Hai, Yu Long, Yan, He Jin, Cai, Yong Qing. Structural screening of phosphorus sulfur ternary hydride PSH6 with a high-temperature superconductivity at 130 GPa[J]. Frontiers of Physics, 2022, 18(2).
Authors:  Hai, Yu Long;  Yan, He Jin;  Cai, Yong Qing
Favorite | TC[WOS]:1 TC[Scopus]:1  IF:6.5/4.5 | Submit date:2023/02/28
High-temperature  Hydrides  Low-pressure  Phosphoruses  Structural Screening  Sulfur  Superconductivity  
Stability of polyphenols in food processing Book chapter
出自: Advances in Food and Nutrition Research:Elsevier, 2022, 页码:1-45
Authors:  Haolin Zhang;  Minglong Wang;  Jianbo Xiao
Favorite | TC[WOS]:6 TC[Scopus]:10 | Submit date:2023/01/30
Polyphenols  Stability  Characterization  Factors  Thermal Processing  Irradiation  Fermentation  High Pressure  Microwave  Drying  Degradation Products  
High-pressure induced acceleration pathways for water diffusion in heavy duty anticorrosion coatings under deep ocean environment: (I) The samples subjected to high-pressure pre-processing Journal article
Shao, Ziya, Ren, Panpan, Jia, Tianyue, Lei, Bing, Feng, Zhiyuan, Guo, Honglei, Chen, Shan, Zhang, Ping, Meng, Guozhe. High-pressure induced acceleration pathways for water diffusion in heavy duty anticorrosion coatings under deep ocean environment: (I) The samples subjected to high-pressure pre-processing[J]. Progress in Organic Coatings, 2022, 170, 106948.
Authors:  Shao, Ziya;  Ren, Panpan;  Jia, Tianyue;  Lei, Bing;  Feng, Zhiyuan; et al.
Favorite | TC[WOS]:10 TC[Scopus]:11  IF:6.5/6.0 | Submit date:2022/08/02
Failure Behavior  Glass Flakes  Cracks  Voids  High-pressure Gas Mass  
High Hydrostatic Pressure-Based Combination Strategies for Microbial Inactivation of Food Products: The Cases of Emerging Combination Patterns Journal article
Qiang Xia, Qianqian Liu, Gabriela I. Denoya, Caijiao Yang, Francisco J. Barba, Huaning Yu, Xiaojia Chen. High Hydrostatic Pressure-Based Combination Strategies for Microbial Inactivation of Food Products: The Cases of Emerging Combination Patterns[J]. Frontiers in Nutrition, 2022, 9, 878904.
Authors:  Qiang Xia;  Qianqian Liu;  Gabriela I. Denoya;  Caijiao Yang;  Francisco J. Barba; et al.
Favorite | TC[WOS]:7 TC[Scopus]:7  IF:4.0/4.4 | Submit date:2022/08/02
Combined Techniques  High Hydrostatic Pressure  Inactivation Efficiencies  Plant-based Foods  Process Development And Integration  
An untargeted metabolomic insight into the high-pressure stress effect on the germination of wholegrain Oryza sativa L. Journal article
Ruan, Yifan, Cai, Zhendong, Deng, Yun, Pan, Daodong, Zhou, Changyu, Cao, Jinxuan, Chen, Xiaojia, Xia, Qiang. An untargeted metabolomic insight into the high-pressure stress effect on the germination of wholegrain Oryza sativa L.[J]. FOOD RESEARCH INTERNATIONAL, 2020, 140, 109984.
Authors:  Ruan, Yifan;  Cai, Zhendong;  Deng, Yun;  Pan, Daodong;  Zhou, Changyu; et al.
Favorite | TC[WOS]:17 TC[Scopus]:20  IF:7.0/7.4 | Submit date:2021/03/02
High Pressure Stress  Brown Rice  Wholegrain Germination  Nontargeted Metabolomics  Opls-da  Rice Metabolome  Uplc-qtof/ms2  
Novel Fe-based nanoglass as efficient noble-metal-free electrocatalyst for alkaline hydrogen evolution reaction Journal article
Wu,Kaiyao, Meng,Yuying, Xu,Jincheng, Edalati,Kaveh, Shao,Huaiyu, Li,Wei, Lin,Huai Jun. Novel Fe-based nanoglass as efficient noble-metal-free electrocatalyst for alkaline hydrogen evolution reaction[J]. SCRIPTA MATERIALIA, 2020, 188, 135-139.
Authors:  Wu,Kaiyao;  Meng,Yuying;  Xu,Jincheng;  Edalati,Kaveh;  Shao,Huaiyu; et al.
Favorite | TC[WOS]:24 TC[Scopus]:23  IF:5.3/5.7 | Submit date:2021/03/11
Hydrogen Evolution Reaction  Fe-based Alloy Catalyst  Nanoglass  Amorphous Alloys  High-pressure Torsion  
Nonthermally driven volatilome evolution of food matrices: The case of high pressure processing Journal article
Xia, Qiang, Zheng, Yuanrong, Liu, Zhenmin, Cao, Jinxuan, Chen, Xiaojia, Liu, Lianliang, Yu, Huaning, Barba, Francisco J., Pan, Daodong. Nonthermally driven volatilome evolution of food matrices: The case of high pressure processing[J]. Trends in Food Science and Technology, 2020, 106, 365-381.
Authors:  Xia, Qiang;  Zheng, Yuanrong;  Liu, Zhenmin;  Cao, Jinxuan;  Chen, Xiaojia; et al.
Favorite | TC[WOS]:21 TC[Scopus]:27  IF:15.1/16.4 | Submit date:2021/03/02
Aromas Compounds  Fingerprint  Flavor Tailoring  High Hydrostatic Pressure  Nonthermal Effects  Volatile Organic Compounds  
Nano-Watt Class Energy-Efficient Capacitive Sensor Interface with On-Chip Temperature Drift Compensation Journal article
Tan-Tan Zhang, Man-Kay Law, Pui-In Mak, Mang-I Vai, Rui P. Martins. Nano-Watt Class Energy-Efficient Capacitive Sensor Interface with On-Chip Temperature Drift Compensation[J]. IEEE Sensors Journal, 2018, 18(7), 2870-2882.
Authors:  Tan-Tan Zhang;  Man-Kay Law;  Pui-In Mak;  Mang-I Vai;  Rui P. Martins
Favorite | TC[WOS]:17 TC[Scopus]:19 | Submit date:2019/02/11
Capacitive Sensor Interface  Energy Efficiency  High Accuracy  Mismatch Errors  Pressure Sensor  Temperature Compensation  Two-step Incremental-adc  Ultra-low Power