自催化生长GaSb纳米线及其在高性能紫外-可见-近红外光电探测器中的应用（英文）

本文应用镓金属液滴作为催化剂,采用化学气相沉积方法自催化合成了单晶GaSb纳米线.研究表明该GaSb纳米线为典型的p型半导体,霍尔迁移率为>0.042 cm^2V^-1s^-1.硅基和柔性衬底上构筑的基于GaSb纳米线的光电探测器,具有良好的紫外-可见-近红外宽光谱探测性能.硅基器件对500 nm的可见光响应率可达3.86×10^3A W-1,探测率可达3.15×10^13Jones;柔性器件在保持相似光电性能的同时,具有极好的机械柔韧性和稳定性.本文有助于更好地揭示自催化生长的GaSb纳米线的性能,并为进一步设计基于GaSb纳米线的功能光电器件打下了实验基础.     

ZnO纳米棒/ZnCo2O4纳米片异质结的制备及其光电探测性能

ZnO纳米材料异质结是构筑高性能紫外光电探测器的有力候选之一。本工作中, 设计并制备了一种新型ZnO纳米棒/ZnCo₂O₄纳米片异质结, 研究了其电学性能及光电探测性能。使用油水界面自组装, 将ZnCo₂O₄纳米片在ITO玻璃上组装为均匀的薄膜; 通过调控ZnO种子层厚度, 在ZnCo₂O₄纳米片薄膜上水热生长了取向一致、密度适中的ZnO纳米棒阵列, 获得了高质量的ZnO纳米棒/ZnCo₂O₄纳米片异质结。该异质结具有优良的整流特性, 整流比达到673.7; 其工作在反偏状态时, 光暗电流比超过2个量级, 紫外-可见判别比为29.4, 在光电探测中有良好的波长选择特性。研究表明, 该异质结有潜力应用于构筑高性能紫外光电探测器。     

基于硫化铅量子点和氧化锌纳米颗粒异质结的高性能柔性和宽波段光电探测器

柔性和宽波段的光电探测器在可折叠显示、光通信和环境监测等方面有潜在的应用,因而引起广泛的关注.本文基于硫化铅量子点和氧化锌纳米颗粒异质结制备了柔性光电探测器.该器件表现出从紫外光到近红外光的宽波段光电响应性能.在375nm紫外光照射下,该器件的电流开关比高达7.08×10^3.与单纯的氧化锌纳米颗粒器件相比,基于异质结...     

准一维纳米结构ZnO的制备研究进展

准一维纳米结构ZnO因其优良的光电性质,在制作纳米电子器件和纳米光电子器件等许多领域表现出巨大的应用潜力.对准一维纳米结构ZnO在衬底上的制备生长方法、性质及衬底的影响作了简要的叙述.     

PbS量子点/ZnO纳米片复合膜的制备及其光电化学性能

通过两步法合成PbS量子点(QDs)修饰ZnO纳米片复合膜. 首先利用电化学法在掺氟的SnO₂导电玻璃(FTO)上生长ZnO纳米片, 然后在ZnO纳米片上通过逐次化学浴法沉积PbS量子点形成PbS/ZnO复合膜. 利用扫描电子显微镜(SEM)、X射线衍射仪(XRD)详细表征了样品的表面形貌和晶体结构, 并研究了PbS/ZnO复合膜作为量子点敏化太阳能电池光阳极的紫外-可见吸收谱、光电化学性能和表面光电压谱. 对比ZnO纳米片经PbS量子点修饰前后, 发现PbS量子点修饰后光阳极的光吸收和光伏响应均从紫外区拓宽到了可见光区, 同时光电化学性能有了显著提高, 短路电流密度从敏化前的0.1 mA/cm²增加到0.7 mA/cm², 效率由0.04%增加到0.57%. 与单一ZnO纳米片相比, PbS/ZnO复合膜的表面光伏响应强度明显增强, 说明PbS与ZnO之间形成了有利于光生电荷分离的异质结, 从而导致了PbS/ZnO复合膜光电性能的增加.     

Ag纳米颗粒对ZnO纳米棒阵列膜的光电响应和持续光电导的调控

通过两步法合成了表面修饰Ag纳米颗粒的ZnO纳米棒阵列膜,并检测了该纳米棒阵列膜在波长为365 nm的紫外光照下的时域光电流曲线。与纯ZnO纳米棒阵列膜相比,Ag纳米颗粒修饰后ZnO纳米棒阵列膜在光电响应阶段有更大的响应值,最大达到7 490,约为纯ZnO纳米棒阵列膜响应值的50倍。而且,Ag纳米颗粒对ZnO纳米棒阵列膜弛豫阶段呈现的持续光电导(PPC)效应有很好的调控作用。相同恢复时间内,纯ZnO纳米棒阵列膜光电流恢复效率为25%,Ag纳米颗粒修饰后达到87%。Ag浓度越大,持续光电导(PPC)效应越不明显,这个现象使得通过简单改变表面Ag纳米颗粒的浓度来调控ZnO纳米棒阵列膜的PPC效应成为可能。     

CdSe/CdS纳米颗粒共敏化ZnO光电极的制备及光电化学性能研究

采用电沉积法将CdS和CdSe纳米颗粒沉积在ZnO纳米线阵列上得到CdSe/CdS纳米颗粒共敏化ZnO光电极。利用X射线衍射、扫描电镜、透射电镜和能谱仪等对所得样品结构和形貌进行表征,并通过紫外-可见分光光度计和电化学工作站测试其光吸收性能和光电化学性能。结果发现,相对纳米颗粒单敏化CdS/ZnO光电极而言,纳米颗粒共敏化CdSe/CdS/ZnO光电极具有更好的可见光吸收性能,进而提高短路电流密度和光电转换效率分别到9.56mA/cm2和1.89%。     

基于ZnO半导体纳米线膜的声表面波型紫外探测器

针对传统半导体光电探测器件结构的宽带隙半导体紫外探测器可测信号弱的问题,提出了一种基于ZnO纳米线膜的声表面波型紫外探测器.该探测器利用ZnO纳米线膜的强紫外光电响应特性和声表面波器件的灵敏的声电相互作用机制,将采用高纯锌粉的热蒸发氧化工艺制备的纤锌矿型ZnO纳米线制作在已有声表面波小波传感器上.利用光致发光谱研究发现,由于低维激子限域效应和表面效应,所制作ZnO纳米线敏感膜中的紫外光电效应优于外延ZnO半导体薄膜;同时,基于ZnO纳米线膜的声表面波式紫外探测器在紫外光辐照下该探测器的中心频率减小,损耗增大.实验研究表明该器件能够实现长波紫外光的高灵敏度探测.     

界面工程与等离激元效应协同作用增强的ZnO微米线同质结自驱动紫外探测器（英文）

高灵敏度的自驱动紫外探测器在许多应用中都大有可为.本研究提出了一种一维ZnO基同结光电探测器,它包括表面覆盖着Ag纳米线的锑掺杂ZnO微米线(AgNWs@ZnO:Sb MW)、MgO缓冲纳米层和ZnO薄膜.该探测器在0 V偏压下对紫外光非常敏感,其性能参数包括约7个量级的开关比、292.2 mA W^-1的响应度、6.9×10¹³Jones的比探测率,以及微秒量级的快速响应速度(上升时间16.4μs,下降时间465.1μs).特别是10μW cm^-2的微弱紫外光时接近99.3%的外量子效率.此外,本文系统研究了MgO纳米薄膜和表面修饰AgNWs对探测器件性能增强的机理.作为自驱动光接收器,该光电二极管被进一步集成到能够实时传输信息的紫外通信系统中.此外,基于AgNWs@p-ZnO:Sb MW/i-MgO/n-ZnO的同质结9×9阵列显示出均匀的光响应分布,可用作具有良好空间分辨率的成像传感器.这项研究有望为设计高性能紫外光检测器提供一条具有低功耗和可大规模建造的途径.     

ZnO纳米棒/石墨烯异质结构的应用研究进展

ZnO纳米棒具有优异的光学性质,石墨烯具有优良的电学性质并且可变形,制备出高质量ZnO纳米棒/石墨烯异质结构能够发挥两者协同效应,有望在高性能光电子器件中实现重要应用。综述了近几年来国内外关于ZnO纳米棒/石墨烯异质结构的最新研究进展,重点包括该结构的各种制备技术及特点,该结构在发光器件、太阳能电池器件、光电探测器以及光催化剂等方面的应用研究进展,最后展望了其未来发展趋势和研究重点。     

Solution-processed,flexible and broadband photodetector based on CsPbBr_3/PbSe quantum dot heterostructures

Due to their promising applications in foldable displays,optical communication equipment and environmental monitoring systems,flexible and broadband optoelectronic devices have gained extensive attention in recent years.Here,a flexible and broadband photodetector based on CsPbBr₃/PbSe quantum dot(QD) heterostructures is firstly presented.The integrated QD heterostructures possess consecutive detection range from ultraviolet(UV) to long-wave length infrared(LW-IR) regions with efficient light absorption and chemical stability,in comparison with the pristine PbSe QDs.Systematic material characterizations reveal the improved exciton dissociation,carrier transport and carrier lifetime of the QD heterostructures.Flexible photodetector Ag/CsPbBr₃/PbSe/Ag demonstrate a high responsivity of 7.17 A/W with a specific detectivity of 8.97 × 10¹² Jones under 25 μW/cm² 365 nm illumination at 5 V.Furthermore,it could maintain 91.2 %(or 94.9 %) of its initial performance even after bending for thousands of times(or exposing in ambient air for 4 weeks).More importantly,its re s ponse time is shortened more than three orders of magnitude as that of pristine PbSe QDs-based photodetectors.Therefore,it provides a feasible and promising method for the next-generation high-performance broadband photodetectors via constructing heterostructures of various QDs.     

High‐Performance Flexible Photodetectors based on High‐Quality Perovskite Thin Films by a Vapor–Solution Method

Organometal halide perovskites are new light‐harvesting materials for lightweight and flexible optoelectronic devices due to their excellent optoelectronic properties and low‐temperature process capability. However, the preparation of high‐quality perovskite films on flexible substrates has still been a great challenge to date. Here, a novel vapor–solution method is developed to achieve uniform and pinhole‐free organometal halide perovskite films on flexible indium tin oxide/poly(ethylene terephthalate) substrates. Based on the as‐prepared high‐quality perovskite thin films, high‐performance flexible photodetectors (PDs) are constructed, which display a nR value of 81 A W^?1 at a low working voltage of 1 V, three orders higher than that of previously reported flexible perovskite thin‐film PDs. In addition, these flexible PDs exhibit excellent flexural stability and durability under various bending situations with their optoelectronic performance well retained. This breakthrough on the growth of high‐quality perovskite thin films opens up a new avenue to develop high‐performance flexible optoelectronic devices.     

Resonance‐Enhanced Absorption in Hollow Nanoshell Spheres with Omnidirectional Detection and High Responsivity and Speed

Optical resonance formed inside a nanocavity resonator can trap light within the active region and hence enhance light absorption, effectively boosting device or material performance in applications of solar cells, photodetectors (PDs), and photocatalysts. Complementing conventional circular and spherical structures, a new type of multishelled spherical resonant strategy is presented. Due to the resonance‐enhanced absorption by multiple convex shells, ZnO nanoshell PDs show improved optoelectronic performance and omnidirectional detection of light at different incidence angles and polarization. In addition, the response and recovery speeds of these devices are improved (0.8 and 0.7 ms, respectively) up to three orders of magnitude faster than in previous reports because of the existence of junction barriers between the nanoshells. The general design principles behind these hollow ZnO nanoshells pave a new way to improve the performance of sophisticated nanophotonic devices.     

Distinguishable Detection of Ultraviolet,Visible, and Infrared Spectrum with High‐Responsivity Perovskite‐Based Flexible Photosensors

Distinguishable detection of the ultraviolet, visible, and infrared spectrum is promising and significant for the super visual system of artificial intelligences. However, it is challenging to provide a photosensor with such broad spectral response ability. In this work, the ultraviolet, visible, and infrared spectrum is distinguished by developing serial photosensors based on perovskite/carbon nanotube hybrids. Oraganolead halide perovskites (CH₃NH₃PbX₃) possess remarkable optoelectronic properties and tunable optical band gaps by changing the halogens, and integration with single‐walled carbon nanotubes can further improve their photoresponsivities. The CH₃NH₃PbCl₃‐based photosensor shows a responsivity up to 10⁵ A W^?1 to ultraviolet and no obvious response to visible light, which is superior to that of most ultraviolet sensors. The CH₃NH₃PbBr₃‐based photosensor exhibits a high responsivity to visible light. Serial devices of the two hybrid photosensors with comparable electric and sensory performances can distinguish the spectrum of ultraviolet, visible, and infrared even with varying light intensities. The photosensors also demonstrate excellent mechanical flexibility and bending stability. By taking full advantages of the oraganolead halide perovskites, this work provides flexible high‐responsivity photosensors specialized for ultraviolet, and gives a simple strategy for distinguishable detection of ultraviolet, visible, and infrared spectrum based on the serial flexible photosensors.     

Effect of oxygen annealing on the ultraviolet photoresponse of P-NiO-nanoflower/n-ZnO-nanowire heterostructures

A transparent ultraviolet (UV) sensor using nanoheterojunctions (NHJs) composed of p-type NiO nanoflowers (NFs) and n-type ZnO nanowires (NWs) was prepared through a sequential low-temperature hydrothermal-growth process. The devices that were annealed in an oxygen (O2) ambient exhibited better rectification behavior (I forward/I reverse = 427), a lower forward threshold voltage (V(th) = 0.98 V), a lower leakage current (1.68 x 10(-5) A/cm2), and superior sensitivity (I uv/I dark = 57.8; I visible/I dark = 1.25) to UV light (lambda = 325 nm) than the unannealed devices. The remarkably improved device performances and optoelectronic characteristics of the annealed p-NiO-NF/n-ZnO-NW NHJs can be associated with their fewer structural defects, fewer interfacial defects, and better crystallinity. A stable and repeatable operation of dynamic photoresponse was also observed in the annealed devices. The excellent sensitivity and repeatable photoresponse to UV light of the hydrothermally grown p-NiO-NF/n-ZnO-NW NHJs annealed in a suitable O2 ambient indicate that they can be applied to nano-integrated optoelectronic devices.     

2D In2S3 Nanoflake Coupled with Graphene toward High‐Sensitivity and Fast‐Response Bulk‐Silicon Schottky Photodetector

Silicon‐based electronic devices, especially graphene/Si photodetectors (Gr/Si PDs), have triggered tremendous attention due to their simple structure and flexible integration of the Schottky junction. However, due to the relatively poor light–matter interaction and mobility of silicon, these Gr/Si PDs typically suffer an inevitable compromise between photoresponsivity and response speed. Herein, a novel strategy for coupling 2D In₂S₃ with Gr/Si PDs is demonstrated. The introduction of the double‐heterojunction design not only strengthens the light absorption of graphene/Si but also combines the advantages of the photogating effect and photovoltaic effect, which suppresses the dark current, accelerates the separation of photogenerated carriers, and brings photoconductive gain. As a result, In₂S₃/graphene/Si devices present an ultrahigh photoresponsivity of 4.53 × 10⁴ A W^?1 and fast response speed less than 40 µs, simultaneously. These parameters are an order of magnitude higher than pristine Gr/Si PDs and among the best values compared with reported 2D materials/Si heterojunction PDs. Furthermore, the In₂S₃/graphene/Si PD expresses outstanding long‐term stability, with negligible performance degradation even after 1 month in air or 1000 cycles of operation. These findings highlight a simple and novel strategy for constructing high‐sensitivity and ultrafast Gr/Si PDs for further optoelectronic applications.     

An All‐Freeze‐Casting Strategy to Design Typographical Supercapacitors with Integrated Architectures

The emergence of flexible and wearable electronics has raised the demand for flexible supercapacitors with accurate sizes and aesthetic shapes. Here, a strategy is developed to prepare flexible all‐in‐one integrated supercapacitors by combining all‐freeze‐casting with typography technique. The continuous seamless connection of all‐in‐one supercapacitor devices enhances the load and/or electron transfer capacity and avoids displacing and detaching between their neighboring components at bending status. Therefore, such a unique structure of all‐in‐one integrated devices is beneficial for retaining stable electrochemical performance at different bending levels. More importantly, the sizes and aesthetic shapes of integrated supercapacitors could be controlled by the designed molds, like type matrices of typography. The molds could be assembled together and typeset randomly, achieving the controllable construction and series and/or parallel connection of several supercapacitor devices. The preparation of flexible integrated supercapacitors will pave the way for assembling programmable all‐in‐one energy storage devices into highly flexible electronics.     

Flexible Visible‐Light Photodetectors with Broad Photoresponse Based on ZrS3 Nanobelt Films

Two new flexible visible‐light photodetectors based on ZrS₃ nanobelts films are fabricated on a polypropylene (PP) film and printing paper, respectively, by an adhesive‐tape transfer method, and their light‐induced electric properties are investigated in detail. The devices demonstrate a remarkable response to 405 to 780 nm light, a photocurrent that depends on the optical power and light wavelength, and an excellent photoswitching effect and stability. This implies that ZrS₃ nanobelts are prospective candidates for high‐performance nanoscale optoelectronic devices that may be practically applied in photodetection of visible to near infrared light. The facile fabrication method is extendable to flexible nanodevices with different nanostructures.     

Flexible Transparent and Free‐Standing SiC Nanowires Fabric: Stretchable UV Absorber and Fast‐Response UV‐A Detector

Transparent and flexible materials are desired for the construction of photoelectric multifunctional integrated devices and portable electronics. Herein, 2H‐SiC nanowires are assembled into a flexible, transparent, self‐standing nanowire fabric (FTS‐NWsF). The as‐synthesized ultralong nanowires form high‐quality crystals with a few stacking faults. The optical transmission spectra reveal that FTS‐NWsF absorbs most incident 200–400 nm light, but remains transparent to visible light. A polydimethylsiloxane (PDMS)–SiC fabric–PDMS sandwich film device exhibits stable electrical output even when repeatedly stretched by up to 50%. Unlike previous SiC nanowires in which stacking faults are prevalent, the transparent, stretchable SiC fabric shows considerable photoelectric activity and exhibits a rapid photoresponse (rise and decay time < 30 ms) to 340–400 nm light, covering most of the UV‐A spectral region. These advances represent significant progress in the design of functional optoelectronic SiC nanowires and transparent and stretchable optoelectronic systems.