二维半导体材料与器件——从传统二维光电材料到石墨炔

近年来,二维半导体材料由于其独特的材料结构和电子输运特性得到了科学界的广泛关注,被应用于光电器件、催化和生物传感器等领域。本文系统概述了传统二维材料以及新兴二维材料石墨炔的发现和发展历程。重点聚焦在二维材料在光探测器领域中的应用,探讨了不同二维材料体系及器件结构对光探测器性能的影响;并详细介绍了新兴二维材料——石墨炔,及其合成和应用。展望了传统二维材料及石墨炔在光电转换器件的应用中所面临的机遇和挑战。     

二维半导体材料与器件——从传统二维光电材料到石墨炔

近年来,二维半导体材料由于其独特的材料结构和电子输运特性得到了科学界的广泛关注,被应用于光电器件、催化和生物传感器等领域。本文系统概述了传统二维材料以及新兴二维材料石墨炔的发现和发展历程。重点聚焦在二维材料在光探测器领域中的应用,探讨了不同二维材料体系及器件结构对光探测器性能的影响;并详细介绍了新兴二维材料——石墨炔,及其合成和应用。展望了传统二维材料及石墨炔在光电转换器件应用中所面临的机遇和挑战。     

二维钙钛矿材料及其在光电器件中的应用

二维钙钛矿作为一种新型光电材料,既具有二维材料的可溶液加工、柔性、可穿戴性以及廉价容易制备等特点,又具备钙钛矿材料结晶度高、载流子迁移率高、激子束缚能低、量子效率高、吸收光谱宽、光吸收系数高和能耗损失低等特性,已经成为材料研究领域的热点而受到广泛关注。本文深入分析了二维钙钛矿材料的组成特点及结构构建规则,探究了其光电特性、能带性质以及非线性光学性质等,对二维钙钛矿光电材料常见的两大类制备方法液相法和气相法进行了归纳,总结了二维钙钛矿材料在太阳能电池、光电探测器、发光二极管、场效应晶体管和激光等光电器件领域的应用现状,最后对该类材料目前存在的主要问题及未来发展前景进行了展望,以期为设计制备高性能二维钙钛矿光电材料提供参考。     

二维半导体材料纳米电子器件和光电器件

近年来,随着各领域对微电子器件集成度及性能要求的不断提高,发展基于二维半导体材料的新型高性能功能性器件成为了突破当前技术瓶颈的重要环节和关键方向。目前,作为新型二维半导体材料的代表,二维过渡金属二硫化物、二维黑磷以及范德瓦尔斯异质结凭借其在电学、热学、机械、光学等方面的优异性能已经成为了发展高性能纳米电子器件和光电器件的最具潜力的材料之一。在本综述中,首先概述了几种用于纳米器件的常见二维材料,分析了材料的结构、性能及其在纳米器件中的应用,其次重点对基于过渡金属二硫化物、黑磷以及由其衍生的范德瓦尔斯异质结的纳米电子器件和光电器件的最新研究进展进行讨论,最后对目前二维半导体纳米器件所面临的挑战以及未来的发展方向进行总结及分析,从而为未来发展高性能功能性纳米器件提供支持。     

钙钛矿阵列化组装及其多功能探测器的应用

钙钛矿材料优异的光电性能使其在高集成、 高性能、 多功能光电探测领域具有广泛的应用前景. 近年来, 科研人员致力于钙钛矿阵列化探测器的研究, 并取得了一系列重要的成果. 本文重点评述了钙钛矿材料的阵列化及其多功能探测器的制备和应用, 介绍了钙钛矿材料的结构分类、 阵列化集成方法及光电探测器的基本器件类型和性能指标, 并进一步阐述了基于钙钛矿一维阵列的高性能光电探测器及其多功能探测器的相关应用研究进展. 最后, 对该研究领域未来的发展方向进行了总结和展望.     

二维黑磷的结构、制备和性能

磷有多种同素异构体: 红磷、白磷、黑磷, 其中黑磷热力学稳定. 二维材料因其低维效应而备受关注, 而近期二维黑磷的成功制备使其成为二维材料的新成员. 二维黑磷是带隙可调的片层结构半导体材料, 在光电领域有很大的潜力, 因而备受瞩目. 本文大量引用参考文献, 综述了黑磷的结构、制备方法, 并详细介绍了二维黑磷的各种性质及其器件性能的研究, 以及化学稳定性及防降解措施. 最后分析了二维黑磷的研究发展趋势.     

二硫化钨纳米材料的应用研究现状

近年来,二硫化钨作为具有类石墨烯结构的二维材料,由于具有优异的电学、光学和催化性能得到了广泛研究.本文介绍了二硫化钨纳米材料的结构性质,并综述了二硫化钨纳米材料在润滑材料、催化领域、能量储存、光电器件和微波吸收领域的应用研究现状,最后总结了二硫化钨纳米材料研究中存在的问题,并展望了其发展前景.     

二维硫化钼基原子晶体材料的化学气相沉积法制备及其器件

二维过渡族金属硫属化合物因其带隙具有强烈的层数依赖性而在电子器件方面具有广泛的应用前景.其中单层二硫化钼(MoS₂)是该系列材料中最典型的一种直接带隙半导体,它具有优异的光、电、磁、热和力学性能.二维MoS₂有望在光电探测、光伏器件、场效应晶体管、存储器件、谷电子和自旋器件、温差电器件、微纳机电器件和系统等方面得以广泛应用.化学气相沉积(CVD)法已成为制备二维过渡族金属硫属化合物如MoS₂、MoSe₂、WS₂和WSe₂等原子层薄膜的主要手段,尤其科学界利用CVD法对二维MoS₂材料进行了深入的制备探索,通过该方法制备的MoS₂薄膜在电子和光电器件方面已经有广泛研究.本文将从二维MoS₂的基本物性出发,详细介绍CVD法制备MoS₂的各种工艺过程,如热分解硫代硫酸盐法、硫化Mo(MoO_3-x)薄膜制备法、MoO_3-x粉体与硫属前驱体气相合成法和钼箔表面直接硫化法,并介绍了基于MoS₂的二维异质结构筑方法.在制备材料的基础上,详细阐述了二维MoS₂在场效应晶体管、光电探测器、柔性电子器件以及异质结器件方面的应用,并展望了二维材料在半导体器件中的应用前景.     

自卷曲技术在微型储能器件上的应用

微型能源存储器件在可穿戴电子产品、微型自驱动探测器等领域有重要的应用前景,同时为研究储能器件电极结构、电子/离子传导率以及电化学动力学之间的内在联系提供了理想的平台。自卷曲技术是利用材料内部存在的残余应力而实现二维薄膜材料自行弯曲的一种方法。相比于传统微纳制备工艺,这种方法可以在微米尺度下将二维薄膜电极材料有序卷曲排列,为微型储能器件的制备提供了有效、便捷的途径。本文介绍了近些年自卷曲技术在微型能源存储器件上的重要进展,其中包括材料自卷曲的原理、自卷曲电极及其储能性质,并以此为基础,着重阐述了自卷曲技术制备单根管微型锂离子电池和电容阵列的应用实例。总结并展望了自卷曲技术在微型储能器件应用上的未来挑战和重要机遇。     

大尺寸二维卤化物钙钛矿铁电晶体的生长及偏振光电探测性能研究※

低维半导体材料, 尤其是近些年快速发展的二维卤化物钙钛矿材料, 因其固有的结构各向异性、独特的量子限域效应和优异的半导体特性, 在偏振光电探测等领域展现出巨大的应用潜力. 其中, 铁电极化所产生的体光伏效应为实现高灵敏的偏振光电探测提供了一种简单有效的途径. 然而二维卤化物钙钛矿铁电体的大尺寸晶体生长仍然是其在光电器件应用中所面临的一个科学难题. 本工作中, 利用溶液降温法生长出了厘米级尺寸的高质量二维卤化物钙钛矿(iPA)₂EA₂Pb₃I₁₀ (iPA为异戊胺, EA为乙胺)铁电单晶, 其最大晶体尺寸达15 mm×15 mm×3 mm. 实验结果表明二维钙钛矿结构赋予(iPA)₂EA₂Pb₃I₁₀晶体强的光学各向异性、窄的光学带隙(1.80 eV)和极其优异的光电特性(光电响应开关比达到10³). 更重要的是, 基于(iPA)₂EA₂Pb₃I₁₀铁电单晶组装的光电探测器在弱偏振光的照射下表现出极其优异的光电特性, 包括大二色比(2.3)、高响应度(193 mA•W^–1)和探测率(7.0×10¹¹ Jones), 超过大多数基于材料本征光学各向异性的光电探测器件. 这项工作不仅为高度各向异性卤化物钙钛矿铁电体的晶体生长指明了方向, 而且推动了铁电材料在高性能偏振光电探测器等方面的应用.     

Recent Advances in Two-dimensional Materials for Electrochemical Energy Storage and Conversion

With the increased energy demand,developing renewable and clean energy technologies becomes more and more significant to mitigate climate warming and alleviate the environmental pollution.The key point is design and synthesis of low cost and efficient materials for a wide variety of electrochemical reactions.Over the past ten years,two-dimensional(2D)nanomaterials that graphene represents have been paid much attention as a class of the most promising candidates for heterogeneous electrocatalysts in electrochemical storage and conversion.Their unique properties,such as good chemical stability,good flexibility,and good electronic properties,along with their nanosized thickness and large specific area,make them exhibit comprehensively good performances for energy storage and conversion.Here,we present an overview on the recent advances in electrochemical applications of graphene,graphdiyne,transition metal dichalcogenides(TMDs),and MXenes for supercapacitors(SCs),oxygen reduction reaction(ORR),and hydrogen evolution reaction(HER).     

Three-dimensional architectures constructed using two-dimensional nanosheets

Two-dimensional(2D) nanomaterials such as transition metal dichalcogenides(TMDs) and graphene have attracted extensive interest as emergent materials, owing to their excellent properties that favor their future use in electronic devices, catalysis, optics, and biological- or energy-relevant areas. However, 2D nanosheets tend to easily restack and condense, which weakens their performance in many of these applications. Assembling these 2D nanosheets as building blocks for three-dimensional(3D) architectures not only maintains the intrinsic performances of the 2D nanostructures but also synergistically makes use of the advantages of the 3D microstructures to improve the overall material properties. In this critical review, we will highlight recent developments of sundry 2D nanosheet-assembled 3D architectures, including their design, synthesis, and potential applications. Their controllable syntheses, novel structures, and potential applications will be systematically explained, analyzed, and summarized. In the end, we will offer some perspective on the challenges facing future advancement of this field.     

基于液相法二维异质结的空间结构可控制备

The research in two-dimensional (2D) materials, such as graphene, transition metal dichalcogenides (TMDs) and black phosphorus, has been further flourished with the recent emergence of heterostructures composed of dissimilar 2D materials. The interfacing/coupling between different constituent components in a heterostructure has given rise to interesting phenomena and useful properties. For example, depending on the type of 2D materials, the distance and the kind of bonding between them, as well as the crystalline property of the hetero-interface, the interface may provide charge traps, exciton recombination centers, or bridges for effective charge/energy transfer. It has also been found that the spatial arrangement in addition to the composition of the constituents is an important factor influencing the overall properties of the heterostructures. Although many methods, such as dry transfer and vapor-phased growth are able to yield heterostructures from pristine or highly crystalline 2D crystals with spatial control, such as vertical heterostructures and lateral heterostructures, these methods are generally not scalable, which has restricted the use of the obtained heterostructures mostly to fundamental studies. The solution-phased synthesis methods, such as solvothermal/hydrothermal synthesis, electrochemical deposition and hot-injection method, may be more suitable for mass production of functional heterostructures despite the relatively low product quality. In the past couple of years, a diverse kinds of hetero/hybrid structures of 2D materials have been prepared successfully in wet-chemical processes. However, precise control over the geometric arrangement of the constituent components has been challenging in solution. Currently, four types of heterostructures including 2D crystals grown on a larger 2D template, vertical heterostructures, lateral heterostructures, and core-shell heterostructures have been prepared in solution. For the first type, flexible 2D nanosheets such as graphene and monolayer TMDs are used as synthesis templates to support the nucleation and growth of other 2D crystals. For vertical heterostructures, relatively rigid nanoplates are used to allow continuous deposition of 2D layers of other materials to form sandwich-like structures. The formation of lateral heterostructures requires edge growth on existing 2D materials without basal deposition, and therefore other methods such as cation exchange can be used as alternative routes. The preparation of core-shell 2D heterostructures generally involves both epitaxial edge growth and basal deposition and has been realized in both metallic and semiconductor structures. In this review, these kinds of heterostructures based on 2D materials will be discussed in terms of their synthesis methods, properties and possible applications. In addition, we will discuss the challenges and possible opportunities in this research direction.     

Encapsulation strategies on 2D materials for field effect transistors and photodetectors

Two-dimensional(2D) layered materials provide a promising alternative solution for overcoming the scaling limits in conventional Si-based devices. However, practical applications of 2D materials are facing crucial bottlenecks, particularly that arising from the instability under ambient condition. The studies of degradation mechanisms and protecting strategies for overcoming the ambient instability of 2D materials have attracted extensive research attentions, both experimentally and theoreticall...     

Advances in two-dimensional heterostructures by mono-element intercalation underneath epitaxial graphene

Two-dimensional (2D) materials have displayed many remarkable physical properties, including 2D superconductivity, magnetism, and layer-dependent bandgaps. However, it is difficult for a single 2D material to meet complex practical requirements. Heterostructures obtained by vertically stacking different kinds of 2D materials have extensively attracted researchers’ attention because of their rich electronic features. With heterostructures, the constraints of lattice matching can be overcome. Meanwhile, high application potential has been explored for electronic and optoelectronic devices, including tunneling transistors, flexible electronics, and photodetectors. Specifically, graphene-based van der Waals heterostructures (vdWHs) by intercalation are emerging to realize various functional heterostructures-based electronic devices. Intercalating atoms under epitaxial graphene can efficiently decouple graphene from the substrate, and is expected to realize rich novel electronic properties in graphene. In this study, we systematically review the progress of the mono-element intercalation in graphene-based vdWHs, including the intercalation mechanism, intercalation-modified electronic properties, and the practical applications of 2D intercalated heterostructures. This work would inspire edge-cutting ideas in the scientific frontiers of 2D materials.     

Recent Progress in Two-dimensional Nanomaterials Following Graphene for Improving Fire Safety of Polymer (Nano)composites

The high fire safety of polymer nanocomposites is being pursued by research institutions around the world. In addition to intrinsic flame retardancy strategy, the additive-type flame retardants have attracted increasing attention due to low commercial cost and easy fabrication craft. However, traditional additive-type flame retardants usually need high addition amount to achieve a desirable effect, which causes many side-effects on the overall performance of polymer materials, such as deteriorated mechanical property and processability. At present, two-dimensional(2 D) nanomaterials have also been applied to reduce the fire hazards of polymer(nano)composites with the coupling of barrier function and catalysis as well as carbonization effect. Even though most research work mainly focus on graphene-based flame retardants, more emerging two-dimensional nanomaterials are taking away research attention, due to their complementary and unique properties, mainly including hexagonal boron nitride(h-BN), molybdenum disulfide(MoS_2), metal organic frameworks(MOF), carbon nitride(CN),titanium carbide(MXene) and black phosphorene(BP). In this review, except for graphene, the flame retardant mechanism involving different layered nanomaterials are also reviewed. Meanwhile, the functionalization method and flame retardancy effect of different layered nanomaterials are emphatically discussed for offering an effective reference to solve the fire hazards of polymer materials. Moreover, this work objectively evaluates the practical significance of polymer/layered nanomaterials composites for industrial application.     

Sensitive,Fast, Solution‐Processed Ultraviolet Detectors Based on Passivated Zinc Oxide Nanorods

Solution‐processed ultraviolet photodetectors based on passivated and unpassivated zinc oxide (ZnO) nanorods, in which the ZnO nanoparticles are synthesized by a hydrothermal method, are demonstrated and characterized. Photoconductive photodetectors fabricated using simple solution processing have recently been shown to exhibit high gains and outstanding sensitivities. One ostensible disadvantage of exploiting photoconductive gain is that the temporal response is limited by the release of carriers from trap states. Herein, specific chemical species are introduced onto the surfaces of ZnO nanoparticles to produce desired trap states with a carefully selected lifetime. Compared with conventional photodetectors based on ZnO nanoparticles, the proposed UV photodetectors have much higher photoresponses and faster response times in the UV region. The photoconductive gain of the fabricated photodetectors varies from 26.83 to 2.32×10² for passivated samples, which indicates high gain. The best temporal response for the fabricated detectors is 34 ms rise time and 132 ms decay time for ZnO nanoparticles passivated by hexamethylenetetramine.     

层状双金属氢氧化物/石墨烯复合材料及其在电化学能量存储与转换中的应用

高效的电化学能量存储与转换功能材料及其器件近年来受到了人们的广泛关注。层状双金属氢氧化物/石墨烯（LDH/G）复合物就是一类重要的能源材料。它们兼具LDH和石墨烯的优异的物理、化学性能,同时克服了LDH导电性差和石墨烯片易于团聚的问题;在超级电容器和电化学催化分解水等方面具有广泛应用。本文综述了LDH与化学修饰石墨烯（氧化石墨烯,还原氧化石墨烯及其衍生物）的有效复合的方法及其在电化学能量存储与转换领域中的应用,特别是关于基于该类材料的超级电容器及电化学析氧反应催化的研究;对LDH/G复合材料研究领域中的挑战和未来发展方向做了展望。     

Metal Phosphorous Trichalcogenides (MPCh3): From Synthesis to Contemporary Energy Challenges

Owing to their unique physical and chemical properties, layered two‐dimensional (2D) materials have been established as the most significant topic in materials science for the current decade. This includes layers comprising mono‐element (graphene, phosphorene), di‐element (metal dichalcogenides), and even multi‐element. A distinctive class of 2D layered materials is the metal phosphorous trichalcogenides (MPCh₃, Ch=S, Se), first synthesized in the late 1800s. Having an unusual intercalation behavior, MPCh₃ were intensively studied in the 1970s for their magnetic properties and as secondary electrodes in lithium batteries, but fell from scrutiny until very recently, being 2D nanomaterials. Based on their synthesis and most significant properties, the present surge of reports related to water‐splitting catalysis and energy storage are discussed in detail. This Minireview is intended as a baseline for the anticipated new wave of researchers who aim to explore these 2D layered materials for their electrochemical energy applications.