Recent findings of two-dimensional(2D)ferroelectric(FE)materials provide more possibilities for the development of 2D FE heterostructure electronic devices based on van der Waals materials and the application of FE de...Recent findings of two-dimensional(2D)ferroelectric(FE)materials provide more possibilities for the development of 2D FE heterostructure electronic devices based on van der Waals materials and the application of FE devices under the limit of atomic layer thickness.In this paper,we report the in-situ fabrication and probing of electronic structures of In_(2)Se_(3)–WSe_(2) lateral heterostructures,compared with most vertical FE heterostructures at present.Through molecular beam epitaxy,we fabricated lateral heterostructures with monolayer WSe_2(three atomic layers)and monolayer In_(2)Se_(3)(five atomic layers).Type-Ⅱband alignment was found to exist in either the lateral heterostructure composed of anti-FEβ′-In_(2)Se_(3) and WSe_(2) or the lateral heterostructure composed of FEβ*-In_(2)Se_(3)and WSe_2,and the band offsets could be modulated by ferroelectric polarization.More interestingly,interface states in both lateral heterostructures acted as narrow gap quantum wires,and the band gap of the interface state in theβ*-In_(2)Se_(3)–WSe_(2)heterostructure was smaller than that in theβ′-In_(2)Se_(3)heterostructure.The fabrication of 2D FE heterostructure and the modulation of interface state provide a new platform for the development of FE devices.展开更多
Strain engineering is a promising method for tuning the electronic properties of two-dimensional(2 D)materials,which are capable of sustaining enormous strain thanks to their atomic thinness.However,applying a large a...Strain engineering is a promising method for tuning the electronic properties of two-dimensional(2 D)materials,which are capable of sustaining enormous strain thanks to their atomic thinness.However,applying a large and homogeneous strain on these 2D materials,including the typical semiconductor MoS_(2),remains cumbersome.Here we report a facile strategy for the fabrication of highly strained MoS_(2) via chalcogenide substitution reaction(CSR)of MoTe_(2) with lattice inheritance.The MoS_(2)resulting from the sulfurized MoTe_(2) sustains ultra large in-plane strain(approaching its strength limit~10%)with great homogeneity.Furthermore,the strain can be deterministically and continuously tuned to~1.5%by simply varying the processing temperature.Thanks to the fine control of our CSR process,we demonstrate a heterostructure of strained MoS_(2)/MoTe_(2)with abrupt interface.Finally,we verify that such a large strain potentially allows the modulation of MoS_(2) bandgap over an ultra-broad range(~1 e V).Our controllable CSR strategy paves the way for the fabrication of highly strained 2D materials for applications in devices.展开更多
A single ZnO nanowire with intrinsic oxygen vacancies is utilized to fabricate four-contact device with focus ion beam lithography technique. Cathodoluminescent spectra indicate strong near-UV and green emission at bo...A single ZnO nanowire with intrinsic oxygen vacancies is utilized to fabricate four-contact device with focus ion beam lithography technique. Cathodoluminescent spectra indicate strong near-UV and green emission at both room temperature and low temperatures. Experimental measurement shows the temperature-dependent conductivity of the ZnO nanowire at low temperatures (below 100 K). The further theoretical analysis confirms that weak localization plays an important role in the electrical transport, which is attributed to the surface states induced by plenty of oxygen vacancies in ZnO nanowire.展开更多
A method of measuring the thermoelectric power of nano-heterostructures based on four-probe scanning tunneling microscopy is presented. The process is composed of the in-situ fabrication of a tungsten-indium tip, the ...A method of measuring the thermoelectric power of nano-heterostructures based on four-probe scanning tunneling microscopy is presented. The process is composed of the in-situ fabrication of a tungsten-indium tip, the precise control of the tip-sample contact and the identification of thermoelectric potential. When the temperature of the substrate is elevated, while that of the tip is kept at room temperature, a thermoelectric potential occurs and can be detected by a current voltage measurement. As an example of its application, the method is demonstrated to be effective to measure the thermoelectric power in several systems. A Seebeck coefficient of tens of IxV/K is obtained in graphene epitaxially grown on Ru (0001) substrate and the thermoelectric potential polarity of this system is found to be the reverse of that of bare Ru (0001) substrate.展开更多
We investigate the thermoelectric-transport properties of metal/graphene/metal hetero-structure. We use a single band tight-binding model to prcsent the two-dimensional electronic band structure of graphene. Using the...We investigate the thermoelectric-transport properties of metal/graphene/metal hetero-structure. We use a single band tight-binding model to prcsent the two-dimensional electronic band structure of graphene. Using the LandauerButticker formula and taking the coupling between graphene and the two electrodes into account, we can calculate the thermoelectric potential and current versus temperature. It is found that in spite of metal electrodes, the carrier type of graphene determines the electron motion direction driven by the difference in temperature between the two electrodes, while for n type graphene, the electrons move along the thermal gradient, and for p type graphene, the electrons move against the thermal gradient.展开更多
基金the National Key R&D Program of China(Grant Nos.2018YFA0305800 and 2018YFA0703700)the National Natural Science Foundation of China(Grant Nos.11974012 and 12134011)the Strategic Priority Research Program of Chinese Academy of Sciences(Grant No.XDB3000000)。
文摘Recent findings of two-dimensional(2D)ferroelectric(FE)materials provide more possibilities for the development of 2D FE heterostructure electronic devices based on van der Waals materials and the application of FE devices under the limit of atomic layer thickness.In this paper,we report the in-situ fabrication and probing of electronic structures of In_(2)Se_(3)–WSe_(2) lateral heterostructures,compared with most vertical FE heterostructures at present.Through molecular beam epitaxy,we fabricated lateral heterostructures with monolayer WSe_2(three atomic layers)and monolayer In_(2)Se_(3)(five atomic layers).Type-Ⅱband alignment was found to exist in either the lateral heterostructure composed of anti-FEβ′-In_(2)Se_(3) and WSe_(2) or the lateral heterostructure composed of FEβ*-In_(2)Se_(3)and WSe_2,and the band offsets could be modulated by ferroelectric polarization.More interestingly,interface states in both lateral heterostructures acted as narrow gap quantum wires,and the band gap of the interface state in theβ*-In_(2)Se_(3)–WSe_(2)heterostructure was smaller than that in theβ′-In_(2)Se_(3)heterostructure.The fabrication of 2D FE heterostructure and the modulation of interface state provide a new platform for the development of FE devices.
基金supported by the National Natural Science Foundation of China(21825103,52001165)Natural Science Foundation of Hubei Province(2019CFA002)+2 种基金Natural Science Foundation of Jiangsu Province(BK20200475)the Fundamental Research Funds for the Central Universities(2019kfy XMBZ018,30921011215)supports from Analytical and Testing Center in Huazhong University of Science and Technology as well as Nanostructure Research Center(NRC)supported by the Fundamental Research Funds for the Central Universities(WUT:2019III012GX,2020III002GX)。
文摘Strain engineering is a promising method for tuning the electronic properties of two-dimensional(2 D)materials,which are capable of sustaining enormous strain thanks to their atomic thinness.However,applying a large and homogeneous strain on these 2D materials,including the typical semiconductor MoS_(2),remains cumbersome.Here we report a facile strategy for the fabrication of highly strained MoS_(2) via chalcogenide substitution reaction(CSR)of MoTe_(2) with lattice inheritance.The MoS_(2)resulting from the sulfurized MoTe_(2) sustains ultra large in-plane strain(approaching its strength limit~10%)with great homogeneity.Furthermore,the strain can be deterministically and continuously tuned to~1.5%by simply varying the processing temperature.Thanks to the fine control of our CSR process,we demonstrate a heterostructure of strained MoS_(2)/MoTe_(2)with abrupt interface.Finally,we verify that such a large strain potentially allows the modulation of MoS_(2) bandgap over an ultra-broad range(~1 e V).Our controllable CSR strategy paves the way for the fabrication of highly strained 2D materials for applications in devices.
基金supported by the National Natural Science Foundation of China (Grant Nos 60771037 and 90406022)the National High Technology Research and Development Program of China (Grant No 2008AA03Z309)the National Key Basic Research Program of China (Grant Nos 2007CB936802 and 2007CB935503)
文摘A single ZnO nanowire with intrinsic oxygen vacancies is utilized to fabricate four-contact device with focus ion beam lithography technique. Cathodoluminescent spectra indicate strong near-UV and green emission at both room temperature and low temperatures. Experimental measurement shows the temperature-dependent conductivity of the ZnO nanowire at low temperatures (below 100 K). The further theoretical analysis confirms that weak localization plays an important role in the electrical transport, which is attributed to the surface states induced by plenty of oxygen vacancies in ZnO nanowire.
基金supported by the National Natural Science Foundation of China (Grant No. 60976089)the National Basic Research Program of China (Grant Nos. 2007CB936802 and 2009CB929103)
文摘A method of measuring the thermoelectric power of nano-heterostructures based on four-probe scanning tunneling microscopy is presented. The process is composed of the in-situ fabrication of a tungsten-indium tip, the precise control of the tip-sample contact and the identification of thermoelectric potential. When the temperature of the substrate is elevated, while that of the tip is kept at room temperature, a thermoelectric potential occurs and can be detected by a current voltage measurement. As an example of its application, the method is demonstrated to be effective to measure the thermoelectric power in several systems. A Seebeck coefficient of tens of IxV/K is obtained in graphene epitaxially grown on Ru (0001) substrate and the thermoelectric potential polarity of this system is found to be the reverse of that of bare Ru (0001) substrate.
基金Project supported by the National Natural Science Foundation of China (Grant No. 60621061)the National Basic Research Program of China (Grant Nos. 2006CB921305 and 2009CB929103)
文摘We investigate the thermoelectric-transport properties of metal/graphene/metal hetero-structure. We use a single band tight-binding model to prcsent the two-dimensional electronic band structure of graphene. Using the LandauerButticker formula and taking the coupling between graphene and the two electrodes into account, we can calculate the thermoelectric potential and current versus temperature. It is found that in spite of metal electrodes, the carrier type of graphene determines the electron motion direction driven by the difference in temperature between the two electrodes, while for n type graphene, the electrons move along the thermal gradient, and for p type graphene, the electrons move against the thermal gradient.
