The van der Waals heterostructures have evolved as novel materials for complementing the Si-based semiconductor technologies.Group-10 noble metal dichalcogenides(e.g.,PtS_(2),PtSe_(2),PdS_(2),and PdSe_(2))have been li...The van der Waals heterostructures have evolved as novel materials for complementing the Si-based semiconductor technologies.Group-10 noble metal dichalcogenides(e.g.,PtS_(2),PtSe_(2),PdS_(2),and PdSe_(2))have been listed into two-dimensional(2D)materials toolkit to assemble van der Waals heterostructures.Among them,PdSe_(2) demonstrates advantages of high stability in air,high mobility,and wide tunable bandgap.However,the regulation of p-type doping of PdSe_(2) remains unsolved problem prior to fabricating p–n junction as a fundamental platform of semiconductor physics.Besides,a quantitative method for the controllable doping of PdSe_(2) is yet to be reported.In this study,the doping level of PdSe_(2) was correlated with the concentration of Lewis acids,for example,SnCl_(4),used for soaking.Considering the transfer characteristics,the threshold voltage(the gate voltage corresponding to the minimum drain current)increased after SnCl_(4) soaking treatment.PdSe_(2) transistors were soaked in SnCl_(4) solutions with five different concentrations.The threshold voltages from the as-obtained transfer curves were extracted for linear fitting to the threshold voltage versus doping concentration correlation equation.This study provides in-depth insights into the controllable p-type doping of PdSe_(2).It may also push forward the research of the regulation of conductivity behaviors of 2D materials.展开更多
Flexible electronics has emerged as a continuously growing field of study.Two-dimensional(2D)materials often act as conductors and electrodes in elec-tronic devices,holding significant promise in the design of high-pe...Flexible electronics has emerged as a continuously growing field of study.Two-dimensional(2D)materials often act as conductors and electrodes in elec-tronic devices,holding significant promise in the design of high-performance,flexible electronics.Numerous studies have focused on harnessing the potential of these materials for the development of such devices.However,to date,the incorporation of 2D materials in flexible electronics has rarely been summa-rized or reviewed.Consequently,there is an urgent need to develop compre-hensive reviews for rapid updates on this evolving landscape.This review covers progress in complex material architectures based on 2D materials,including interfaces,heterostructures,and 2D/polymer composites.Addition-ally,it explores flexible and wearable energy storage and conversion,display and touch technologies,and biomedical applications,together with integrated design solutions.Although the pursuit of high-performance and high-sensitivity instruments remains a primary objective,the integrated design of flexible electronics with 2D materials also warrants consideration.By combin-ing multiple functionalities into a singular device,augmented by machine learning and algorithms,we can potentially surpass the performance of existing wearable technologies.Finally,we briefly discuss the future trajectory of this burgeoning field.This review discusses the recent advancements in flex-ible sensors made from 2D materials and their applications in integrated archi-tecture and device design.展开更多
基金the Natural Science Foundation of Shandong Province for Excellent Young Scholars(No.ZR2022YQ41)the fund(No.SKT2203)from the State Key Laboratories of Transducer Technology,Shanghai Institute of Microsystem and Information Technology+9 种基金Chinese Academy of Sciences for support.This work was partially supported by the National Key Research and Development Program of China(No.2022YFE0124200)the National Natural Science Foundation of China(No.U2241221)W.J.Z.thanks the Major innovation project of Shandong Province(No.2021CXGC010603)the National Natural Science Foundation of China(No.52022037)the Taishan Scholars Project Special Funds(No.TSQN201812083)The project was supported by the Foundation(No.GZKF202107)of State Key Laboratory of Biobased Material and Green PapermakingQilu University of Technology,Shandong Academy of Sciences.M.H.R.thanks the National Natural Science Foundation of China(No.52071225)the National Science Center and the Czech Republic under the ERDF program“Institute of Environmental Technology-Excellent Research”(No.CZ.02.1.01/0.0/0.0/16_019/0000853)the Sino-German Research Institute(No.GZ 1400)for supportS.X.H.thanks the National Natural Science Foundation of China(Nos.21976014 and 22276013)for funding,and thanks the Tianhe2-JK HPC for generous computer time.
文摘The van der Waals heterostructures have evolved as novel materials for complementing the Si-based semiconductor technologies.Group-10 noble metal dichalcogenides(e.g.,PtS_(2),PtSe_(2),PdS_(2),and PdSe_(2))have been listed into two-dimensional(2D)materials toolkit to assemble van der Waals heterostructures.Among them,PdSe_(2) demonstrates advantages of high stability in air,high mobility,and wide tunable bandgap.However,the regulation of p-type doping of PdSe_(2) remains unsolved problem prior to fabricating p–n junction as a fundamental platform of semiconductor physics.Besides,a quantitative method for the controllable doping of PdSe_(2) is yet to be reported.In this study,the doping level of PdSe_(2) was correlated with the concentration of Lewis acids,for example,SnCl_(4),used for soaking.Considering the transfer characteristics,the threshold voltage(the gate voltage corresponding to the minimum drain current)increased after SnCl_(4) soaking treatment.PdSe_(2) transistors were soaked in SnCl_(4) solutions with five different concentrations.The threshold voltages from the as-obtained transfer curves were extracted for linear fitting to the threshold voltage versus doping concentration correlation equation.This study provides in-depth insights into the controllable p-type doping of PdSe_(2).It may also push forward the research of the regulation of conductivity behaviors of 2D materials.
基金supported by National Key Research and Development Program(No.2022YFE0124200)National Natural Science Foundation of China(No.U2241221)+9 种基金J.P.thanks the Natural Science Foundation of Shandong Province for Excellent Young Scholars(YQ2022041)the fund(No.SKT2203)from the State Key Laboratories of Transducer TechnologyShanghai Institute of Microsystem and Information Technology,Chinese Academy of Sciences for support.W.Z.thanks the Major Scientific and Technological Innovation Project of Shandong Province(2021CXGC010603)NSFC(No.52022037)Taishan Scholars Project Special Funds(TSQN201812083)The Project was supported by the Foundation(No.GZKF202107)of State Key Laboratory of Biobased Material and Green PapermakingQilu University of Technology,Shandong Academy of Sciences.M.H.R.thanks NSFC(No.52071225)the National Science Center and the Czech Republic under the European Regional Development Fund(ERDF)“Institute of Environmental Technology-Excellent Research”(No.CZ.02.1.01/0.0/0.0/16_019/0000853)the SinoGerman Center for Research Promotion(SGC)for support(No.GZ 1400).
文摘Flexible electronics has emerged as a continuously growing field of study.Two-dimensional(2D)materials often act as conductors and electrodes in elec-tronic devices,holding significant promise in the design of high-performance,flexible electronics.Numerous studies have focused on harnessing the potential of these materials for the development of such devices.However,to date,the incorporation of 2D materials in flexible electronics has rarely been summa-rized or reviewed.Consequently,there is an urgent need to develop compre-hensive reviews for rapid updates on this evolving landscape.This review covers progress in complex material architectures based on 2D materials,including interfaces,heterostructures,and 2D/polymer composites.Addition-ally,it explores flexible and wearable energy storage and conversion,display and touch technologies,and biomedical applications,together with integrated design solutions.Although the pursuit of high-performance and high-sensitivity instruments remains a primary objective,the integrated design of flexible electronics with 2D materials also warrants consideration.By combin-ing multiple functionalities into a singular device,augmented by machine learning and algorithms,we can potentially surpass the performance of existing wearable technologies.Finally,we briefly discuss the future trajectory of this burgeoning field.This review discusses the recent advancements in flex-ible sensors made from 2D materials and their applications in integrated archi-tecture and device design.
