Subject Code:C02With the support by the National Natural Science Foundation of China,the research team led by Prof.Lin Jinxing(林金星)at the College of Biological Sciences&Biotechnology,Beijing Forestry University...Subject Code:C02With the support by the National Natural Science Foundation of China,the research team led by Prof.Lin Jinxing(林金星)at the College of Biological Sciences&Biotechnology,Beijing Forestry University,overcame the limitations of existing techniques and expanded the study of protein characteristics from the plasma membrane to the vacuole membranes.This study was published in Molecular Plant(2016,DOI:展开更多
"Active" components can be introduced into a passive system to completely change its physical behavior from its typical behavior at thermodynamic equilibrium. To reveal the interaction mechanisms between ind..."Active" components can be introduced into a passive system to completely change its physical behavior from its typical behavior at thermodynamic equilibrium. To reveal the interaction mechanisms between individuals, researchers have designed unique self-propelled particles to mimic the collective behavior of biological systems. This review focuses on recent theoretical and experimental advances in the study of self-propelled particle systems and their individual and collective behaviors. The potential applications of active particles in chemical, biological and environmental sensing and single particle imaging are discussed.展开更多
文摘Subject Code:C02With the support by the National Natural Science Foundation of China,the research team led by Prof.Lin Jinxing(林金星)at the College of Biological Sciences&Biotechnology,Beijing Forestry University,overcame the limitations of existing techniques and expanded the study of protein characteristics from the plasma membrane to the vacuole membranes.This study was published in Molecular Plant(2016,DOI:
基金supported by the National Natural Science Foundation of China (21425519)the Tsinghua University Startup Fund
文摘"Active" components can be introduced into a passive system to completely change its physical behavior from its typical behavior at thermodynamic equilibrium. To reveal the interaction mechanisms between individuals, researchers have designed unique self-propelled particles to mimic the collective behavior of biological systems. This review focuses on recent theoretical and experimental advances in the study of self-propelled particle systems and their individual and collective behaviors. The potential applications of active particles in chemical, biological and environmental sensing and single particle imaging are discussed.
