Calcium carbonate(CaCO_(3))is a crucial mineral with great scientific relevance in biomineralization and geoscience.However,excessive precipitation of CaCO_(3)is posing a threat to industrial production and the aquati...Calcium carbonate(CaCO_(3))is a crucial mineral with great scientific relevance in biomineralization and geoscience.However,excessive precipitation of CaCO_(3)is posing a threat to industrial production and the aquatic environment.The utilization of chemical inhibitors is typically considered an economical and successful route for addressing the scaling issues,while the underlying mechanism is still debated and needs to be further investigated.In this context,a deep understanding of the crystallization process of CaCO_(3)and how the inhibitors interact with CaCO_(3)nuclei and crystals are of great significance in evaluating the performance of scale inhibitors.In recent years,with the rapid development of computing facilities,computer simulations have provided an atomic-level perspective on the kinetics and thermodynamics of possible association events in CaCO_(3)solutions as well as the predictions of nucleation pathway and growth mechanism of CaCO_(3)crystals as a complement to experiment.This review surveys several computational methods and their achievements in this field with a focus on analyzing the functional mechanisms of different types of inhibitors.A general discussion of the current challenges and future directions in applying atomistic simulations to the discovery,design,and development of more effective water-scale inhibitors is also discussed.展开更多
Subject Code:F01With the support by the National Natural Science Foundation of China,the research team led by Prof.Peng Lianmao(彭练矛)and Prof.Zhang Zhiyong(张志勇)at the Key Laboratory for the Physics and Chemistry ...Subject Code:F01With the support by the National Natural Science Foundation of China,the research team led by Prof.Peng Lianmao(彭练矛)and Prof.Zhang Zhiyong(张志勇)at the Key Laboratory for the Physics and Chemistry of Nanodevices and Department of Electronics,Peking University,Beijing,recently reported that carbon nanotube CMOS FETs were scaled down to the 5nm gate length and presented展开更多
基金the financial support from the Natural Sciences and Engineering Research Council(NSERC)under Alliance Program(grant no.ALLRP 557113-20)the Canada Research Chairs Program。
文摘Calcium carbonate(CaCO_(3))is a crucial mineral with great scientific relevance in biomineralization and geoscience.However,excessive precipitation of CaCO_(3)is posing a threat to industrial production and the aquatic environment.The utilization of chemical inhibitors is typically considered an economical and successful route for addressing the scaling issues,while the underlying mechanism is still debated and needs to be further investigated.In this context,a deep understanding of the crystallization process of CaCO_(3)and how the inhibitors interact with CaCO_(3)nuclei and crystals are of great significance in evaluating the performance of scale inhibitors.In recent years,with the rapid development of computing facilities,computer simulations have provided an atomic-level perspective on the kinetics and thermodynamics of possible association events in CaCO_(3)solutions as well as the predictions of nucleation pathway and growth mechanism of CaCO_(3)crystals as a complement to experiment.This review surveys several computational methods and their achievements in this field with a focus on analyzing the functional mechanisms of different types of inhibitors.A general discussion of the current challenges and future directions in applying atomistic simulations to the discovery,design,and development of more effective water-scale inhibitors is also discussed.
文摘Subject Code:F01With the support by the National Natural Science Foundation of China,the research team led by Prof.Peng Lianmao(彭练矛)and Prof.Zhang Zhiyong(张志勇)at the Key Laboratory for the Physics and Chemistry of Nanodevices and Department of Electronics,Peking University,Beijing,recently reported that carbon nanotube CMOS FETs were scaled down to the 5nm gate length and presented
