Abstract
The realization of electrically pumped emitters at micro and nanoscale, especially with flexibility or special shapes is still a goal for prospective fundamental research and application. Herein, zinc oxide (ZnO) microwires were produced to investigate the luminescent properties affected by stress. To exploit the initial stress, room temperature in situ elastic bending stress was applied on the microwires by squeezing between the two approaching electrodes. A novel unrecoverable deformation phenomenon was observed by applying a large enough voltage, resulting in the formation of additional defects at bent regions. The electrical characteristics of the microwire changed with the applied bending deformation due to the introduction of defects by stress. When the injection current exceeded certain values, bright emission was observed at bent regions, ZnO microwires showed illumination at the bent region priority to straight region. The bent emission can be attributed to the effect of thermal tunneling electroluminescence appeared primarily at bent regions. The physical mechanism of the observed thermoluminescence phenomena was analyzed using theoretical simulations. The realization of electrically induced deformation and the related bending emissions in single microwires shows the possibility to fabricate special-shaped light sources and offer a method to develop photoelectronic devices.
Highlights
With the development of manufacturing technology, nano/microstructures have realized their potential in functional optoelectronic devices such as light-emitting devices, diode lasers, and photodetectors [1,2,3,4,5]
zinc oxide (ZnO) microwires were produced by a typical chemical vapor deposition (CVD) technique
Film was deposited on the Si substrate by the magnetron sputtering method, and the substrate was loaded above the ZnO powders
Summary
With the development of manufacturing technology, nano/microstructures have realized their potential in functional optoelectronic devices such as light-emitting devices, diode lasers, and photodetectors [1,2,3,4,5]. ZnO micro/nanowires have an instinctive bend ductility and highly efficient thermoelectricity, it is crucial to explore the ZnO micro/nanowires for various applications with shape plasticity as well as application compatibility [6,7,8,9,10] These micro/nanowires have attracted a lot of interest owing to their unique semiconducting, photoelectric, and piezoelectric properties for plenty of applications in piezo-optoelectronics, such as nanogenerators [11,12,13,14,15], piezoelectric devices, etc., [16,17,18,19,20,21,22,23]. Most of the previous studies have reported that the crystal and electronic structure of the semiconductor nanowires are sensitive to the applied mechanical strain [24].
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