Binary Cu-based chalcogenide thermoelectric materials have attracted a great deal of attention due to their outstanding physical properties and fascinating phase sequence.However,the relatively low figure of merit z T...Binary Cu-based chalcogenide thermoelectric materials have attracted a great deal of attention due to their outstanding physical properties and fascinating phase sequence.However,the relatively low figure of merit z T restricts their practical applications in power generation.A general approach to enhancing z T value is to produce nanostructured grains,while one disadvantage of such a method is the expansion of grain size in heating-up process.Here,we report a prominent improvement of z T in Cu2Te(0.2)Se(0.8),which is several times larger than that of the matrix.This significant enhancement in thermoelectric performance is attributed to the formation of abundant porosity via cold press.These pores with nano-to micrometer size can manipulate phonon transport simultaneously,resulting in an apparent suppression of thermal conductivity.Moreover,the Se substitution triggers a rapid promotion of power factor,which compensates for the reduction of electrical properties due to carriers scattering by pores.Our strategy of porosity engineering by phonon scattering can also be highly applicable in enhancing the performances of other thermoelectric systems.展开更多
A new two-dimensional atomic crystal, monolayer cuprous telluride(Cu2Te) has been fabricated on a grapheneSi C(0001) substrate by molecular beam epitaxy(MBE). The low-energy electron diffraction(LEED) characte...A new two-dimensional atomic crystal, monolayer cuprous telluride(Cu2Te) has been fabricated on a grapheneSi C(0001) substrate by molecular beam epitaxy(MBE). The low-energy electron diffraction(LEED) characterization shows that the monolayer Cu2Te forms ■ superstructure with respect to the graphene substrate. The atomic structure of the monolayer Cu2Te is investigated through a combination of scanning tunneling microscopy(STM) experiments and density functional theory(DFT) calculations. The stoichiometry of the Cu2Te sample is verified by x-ray photoelectron spectroscopy(XPS) measurement. The angle-resolved photoemission spectroscopy(ARPES) data present the electronic band structure of the sample, which is in good agreement with the calculated results. Furthermore, air-exposure experiments reveal the chemical stability of the monolayer Cu2Te. The fabrication of this new 2D material with a particular structure may bring new physical properties for future applications.展开更多
A novel strategy was developed to fabricate FeNx-doped carbon quantum dots(Fe-N-CQDs)to detect Cu^(2+) ions selectively as a fluorescence probe.The Fe-N-CQDs were synthesized by an efficient electrolysis of a carbon c...A novel strategy was developed to fabricate FeNx-doped carbon quantum dots(Fe-N-CQDs)to detect Cu^(2+) ions selectively as a fluorescence probe.The Fe-N-CQDs were synthesized by an efficient electrolysis of a carbon cloth electrode,which was coated with monoatomic ironanchored nitrogen-doped carbon(Fe-N-C).The obtained Fe-N-CQDs emitted blue fluorescence and possessed a quantum yield(QY)of 7.5%.An extremely wide linear relationship between the Cu^(2+) concentration and the fluorescence intensity was obtained in the range from 100 nmol L^(-1) to 1000 nmol L^(-1)(R^(2)=0.997),and the detection limit was calculated as 59 nmol L^(-1).Moreover,the Fe-N-CQDs demonstrated wide range pH compatibility between 2 and 13 due to the coordination between pyridine nitrogen and Fe^(3+),which dramatically reduced the affection of the protonation and deprotonation process between H^(+) and Fe-N-CQDs.It is notable that the Fe-N-CQDs exhibited a rapid response in Cu^(2+) detection,where stable quenching can be completed in 7 s.The mechanism of excellent selective detection of Cu^(2+) was revealed by energy level simulation that the LUMO level of Fe-N-CQDs(-4.37 eV)was close to the redox potential of Cu^(2+),thus facilitating the electron transport from Fe-N-CQDs to Cu^(2+).展开更多
The effects of annealing process on the electrical conductivity and mechanical properties of Cu-Te alloys were studied via AG-10TA electronic universal machine, SB2230 digital electric bridge, SEM and EDS. The results...The effects of annealing process on the electrical conductivity and mechanical properties of Cu-Te alloys were studied via AG-10TA electronic universal machine, SB2230 digital electric bridge, SEM and EDS. The results show that recrystallization and precipitation occur simultaneously during the annealing process of Cu-Te alloys. Tellurium precipitates as Cu2Te second phase. The grain size increases with the increasing of annealing temperature and time. The electrical conductivity increases monotonously. The tensile strength of Cu-Te alloy is higher than that of pure copper.展开更多
在不同温度和不同保温时间条件下对2524铸态合金进行均匀化处理,利用扫描电镜(SEM)、透射电镜(TEM)、差示扫描量热法(DSC)和金相显微镜(OM)等,研究2524铸态合金在均匀化过程中微观组织的变化,并分析在不同的均匀化处理状态下T相(即Al20C...在不同温度和不同保温时间条件下对2524铸态合金进行均匀化处理,利用扫描电镜(SEM)、透射电镜(TEM)、差示扫描量热法(DSC)和金相显微镜(OM)等,研究2524铸态合金在均匀化过程中微观组织的变化,并分析在不同的均匀化处理状态下T相(即Al20Cu2Mn3相)的析出情况。结果表明:2524铸态合金中存在严重的枝晶偏析,大量的非平衡共晶相连续地沿晶界分布,主要的第二相为Al2Cu和Al2Cu Mg;主要合金元素不同程度地富集在晶界,富集程度为Cu>Mg>Mn;最佳的均匀化处理制度为500℃/48 h,均匀化处理后,Al2Cu和Al2Cu Mg基本回溶至基体,只余少量难溶的Al Cu Fe Mn相散布在晶界,该均匀化制度与均匀化动力学方程的计算结果基本一致;随均匀化处理温度升高,T相粒子的尺寸逐渐增大而数目逐渐减少。展开更多
基金Project supported by the National Natural Science Foundation of China(Grant Nos.51771126 and 11774247)the Youth Foundation of Science and Technology Department of Sichuan Province,China(Grant No.2016JQ0051)+2 种基金Sichuan University Outstanding Young Scholars Research Funding(Grant No.2015SCU04A20)the World First-Class University Construction Fundingthe Fundamental and Frontier Research Project in Chongqing(Grant No.CSTC2015JCYJBX0026)
文摘Binary Cu-based chalcogenide thermoelectric materials have attracted a great deal of attention due to their outstanding physical properties and fascinating phase sequence.However,the relatively low figure of merit z T restricts their practical applications in power generation.A general approach to enhancing z T value is to produce nanostructured grains,while one disadvantage of such a method is the expansion of grain size in heating-up process.Here,we report a prominent improvement of z T in Cu2Te(0.2)Se(0.8),which is several times larger than that of the matrix.This significant enhancement in thermoelectric performance is attributed to the formation of abundant porosity via cold press.These pores with nano-to micrometer size can manipulate phonon transport simultaneously,resulting in an apparent suppression of thermal conductivity.Moreover,the Se substitution triggers a rapid promotion of power factor,which compensates for the reduction of electrical properties due to carriers scattering by pores.Our strategy of porosity engineering by phonon scattering can also be highly applicable in enhancing the performances of other thermoelectric systems.
基金Project supported by the National Key Research&Development Program of China(Grant Nos.2016YFA0202300 and 2018YF A0305800)the National Natural Science Foundation of China(Grant Nos.61888102,11604373,61622116,and 51872284)+2 种基金the CAS Pioneer Hundred Talents Program,China,the Strategic Priority Research Program of Chinese Academy of Sciences(Grant Nos.XDB30000000 and XDB28000000)Beijing Nova Program,China(Grant No.Z181100006218023)the University of Chinese Academy of Sciences
文摘A new two-dimensional atomic crystal, monolayer cuprous telluride(Cu2Te) has been fabricated on a grapheneSi C(0001) substrate by molecular beam epitaxy(MBE). The low-energy electron diffraction(LEED) characterization shows that the monolayer Cu2Te forms ■ superstructure with respect to the graphene substrate. The atomic structure of the monolayer Cu2Te is investigated through a combination of scanning tunneling microscopy(STM) experiments and density functional theory(DFT) calculations. The stoichiometry of the Cu2Te sample is verified by x-ray photoelectron spectroscopy(XPS) measurement. The angle-resolved photoemission spectroscopy(ARPES) data present the electronic band structure of the sample, which is in good agreement with the calculated results. Furthermore, air-exposure experiments reveal the chemical stability of the monolayer Cu2Te. The fabrication of this new 2D material with a particular structure may bring new physical properties for future applications.
基金the National Natural Science Foundation of China(Nos.21776302 and 21776308)the Science Foundation of China University of Petroleum,Beijing(No.2462020YXZZ033).
文摘A novel strategy was developed to fabricate FeNx-doped carbon quantum dots(Fe-N-CQDs)to detect Cu^(2+) ions selectively as a fluorescence probe.The Fe-N-CQDs were synthesized by an efficient electrolysis of a carbon cloth electrode,which was coated with monoatomic ironanchored nitrogen-doped carbon(Fe-N-C).The obtained Fe-N-CQDs emitted blue fluorescence and possessed a quantum yield(QY)of 7.5%.An extremely wide linear relationship between the Cu^(2+) concentration and the fluorescence intensity was obtained in the range from 100 nmol L^(-1) to 1000 nmol L^(-1)(R^(2)=0.997),and the detection limit was calculated as 59 nmol L^(-1).Moreover,the Fe-N-CQDs demonstrated wide range pH compatibility between 2 and 13 due to the coordination between pyridine nitrogen and Fe^(3+),which dramatically reduced the affection of the protonation and deprotonation process between H^(+) and Fe-N-CQDs.It is notable that the Fe-N-CQDs exhibited a rapid response in Cu^(2+) detection,where stable quenching can be completed in 7 s.The mechanism of excellent selective detection of Cu^(2+) was revealed by energy level simulation that the LUMO level of Fe-N-CQDs(-4.37 eV)was close to the redox potential of Cu^(2+),thus facilitating the electron transport from Fe-N-CQDs to Cu^(2+).
基金Project(50201010) supported by the National Natural Science Foundation of China Project(20010610013) supported by Dectoral Subject Foundation of Ministry of Eduction
文摘The effects of annealing process on the electrical conductivity and mechanical properties of Cu-Te alloys were studied via AG-10TA electronic universal machine, SB2230 digital electric bridge, SEM and EDS. The results show that recrystallization and precipitation occur simultaneously during the annealing process of Cu-Te alloys. Tellurium precipitates as Cu2Te second phase. The grain size increases with the increasing of annealing temperature and time. The electrical conductivity increases monotonously. The tensile strength of Cu-Te alloy is higher than that of pure copper.
文摘在不同温度和不同保温时间条件下对2524铸态合金进行均匀化处理,利用扫描电镜(SEM)、透射电镜(TEM)、差示扫描量热法(DSC)和金相显微镜(OM)等,研究2524铸态合金在均匀化过程中微观组织的变化,并分析在不同的均匀化处理状态下T相(即Al20Cu2Mn3相)的析出情况。结果表明:2524铸态合金中存在严重的枝晶偏析,大量的非平衡共晶相连续地沿晶界分布,主要的第二相为Al2Cu和Al2Cu Mg;主要合金元素不同程度地富集在晶界,富集程度为Cu>Mg>Mn;最佳的均匀化处理制度为500℃/48 h,均匀化处理后,Al2Cu和Al2Cu Mg基本回溶至基体,只余少量难溶的Al Cu Fe Mn相散布在晶界,该均匀化制度与均匀化动力学方程的计算结果基本一致;随均匀化处理温度升高,T相粒子的尺寸逐渐增大而数目逐渐减少。
