光对ZnO薄膜电致电阻转变效应的调控研究

利用磁控溅射技术在镀铂硅片上制备ZnO薄膜,X射线衍射测试表明ZnO薄膜为纯相结构,原子力显微镜测试显示ZnO薄膜表面平整均匀,均方根粗糙度为1.87nm.在室温下对Au/ZnO/Pt三明治结构的电输运行为进行了研究,结果表明同时存在电致电阻转变效应和光伏效应,并且光照可调控电致电阻.当光强为360μW·cm-2时,电阻调控幅度达78%,这种光调控的电致电阻转变有助于实现多态存储,提高存储密度.     

Optoelectronic memristor for neuromorphic computing

With the need of the internet of things,big data,and artificial intelligence,creating new computing architecture is greatly desired for handling data-intensive tasks.Human brain can simultaneously process and store information,which would reduce the power consumption while improve the efficiency of computing.Therefore,the development of brainlike intelligent device and the construction of brain-like computation are important breakthroughs in the field of artificial intelligence.Memristor,as the fourth fundamental circuit element,is an ideal synaptic simulator due to its integration of storage and processing characteristics,and very similar activities and the working mechanism to synapses among neurons which are the most numerous components of the brains.In particular,memristive synaptic devices with optoelectronic responding capability have the benefits of storing and processing transmitted optical signals with wide bandwidth,ultrafast data operation speed,low power consumption,and low cross-talk,which is important for building efficient brain-like computing networks.Herein,we review recent progresses in optoelectronic memristor for neuromorphic computing,including the optoelectronic memristive materials,working principles,applications,as well as the current challenges and the future development of the optoelectronic memristor.     

Improved photovoltaic effects in Mn-doped BiFeO_3 ferroelectric thin films through band gap engineering

As a low-bandgap ferroelectric material, BiFeO_3 has gained wide attention for the potential photovoltaic applications,since its photovoltaic effect in visible light range was reported in 2009. In the present work, Bi(Fe, Mn)O_3thin films are fabricated by pulsed laser deposition method, and the effects of Mn doping on the microstructure, optical, leakage,ferroelectric and photovoltaic characteristics of Bi(Fe, Mn)O_3 thin films are systematically investigated. The x-ray diffraction data indicate that Bi(Fe, Mn)O_3 thin films each have a rhombohedrally distorted perovskite structure. From the light absorption results, it follows that the band gap of Bi(Fe, Mn)O_3 thin films can be tuned by doping different amounts of Mn content. More importantly, photovoltaic measurement demonstrates that the short-circuit photocurrent density and the open-circuit voltage can both be remarkably improved through doping an appropriate amount of Mn content, leading to the fascinating fact that the maximum power output of ITO/BiFe_(0.7)Mn_(0.3)O_3/Nb-STO capacitor is about 175 times higher than that of ITO/BiFeO_3/Nb-STO capacitor. The improvement of photovoltaic response in Bi(Fe, Mn)O_3 thin film can be reasonably explained as being due to absorbing more visible light through bandgap engineering and maintaining the ferroelectric property at the same time.