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典型文献

Nano-confined superfluid-based highly efficient chemical reaction and signal transmission

文献摘要：

Biological systems are featured by ultralow energy-consumption and ultrahigh efficiency in terms of biosynthesis,energy conversion,and signal transmission(e.g.,signal propaga-tion along the neuronal axon).For example,enzymatic biosynthe-sis in yeast DNA polymerase achieves high flux,100％selectivity,and low reaction activation energy under mild physiological condi-tions[1].Another example,human brains rapidly handle a huge amount of neural data with an ultralow energy consumption(～60 W).The remarkable phenomena aforementioned are attribu-ted to the ultrafast collective transport of molecules/ions through the biological nanochannels[2].For example,the transport rates of potassium ions and water molecules through potassium channel and water channel are about 108 ions/s and 3.9×109 molecules/s per channel(Fig.1a)[3,4],respectively.Here,the nanoconfinement refers to nanoscaled channels with confined spaces for ions/-molecules to transport,whereas superfluid is recently introduced to define the ultrafast and efficient ion/molecule fluid[2].

文献关键词：

中图分类号：

[1] 医药、卫生（R） / 药学（R9） / 药理学（R96） / 实验药理学（R965）

[2] 自动化技术、计算机技术（TP） / 计算技术、计算机技术（TP3） / 计算机的应用（TP39） / 信息处理(信息加工)（TP391）

[3] 自动化技术、计算机技术（TP） / 计算技术、计算机技术（TP3） / 计算机的应用（TP39） / 信息处理(信息加工)（TP391） / 模式识别与装置（TP391.4）

作者姓名：

Linfeng Chen;Dicky Pranantyo;Fan Xia

作者机构：

State Key Laboratory of Biogeology and Environmental Geology,Engineering Research Center of Nano-Geomaterials of Ministry of Education,Faculty of Material Science and Chemistry,China University of Geosciences,Wuhan 430074,China;Antimicrobial Resistance Interdisciplinary Research Group,Singapore-MIT Alliance for Research and Technology,Singapore 138602,Singapore

文献出处：

科学通报（英文版）

引用格式：

[1]Linfeng Chen;Dicky Pranantyo;Fan Xia-.Nano-confined superfluid-based highly efficient chemical reaction and signal transmission)[J].科学通报（英文版）,2022(15):1509-1512

A类：

biosynthe,attribu,nanoscaled

B类：

Nano,confined,superfluid,highly,efficient,chemical,reaction,signal,transmission,Biological,systems,are,featured,by,ultralow,energy,consumption,ultrahigh,efficiency,terms,biosynthesis,conversion,propaga,along,neuronal,axon,For,example,enzymatic,yeast,polymerase,achieves,flux,selectivity,activation,under,mild,physiological,condi,tions,Another,human,brains,rapidly,handle,huge,amount,neural,data,remarkable,phenomena,aforementioned,ted,ultrafast,collective,transport,molecules,through,biological,nanochannels,rates,potassium,water,about,Fig,1a,respectively,Here,nanoconfinement,refers,spaces,whereas,recently,introduced,define

AB值：

0.569747

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