Asymmetric doping channel (AC) partially depleted (PD) silicon-on-insulator (SOI) devices are simulated using two-dimensional simulation software. The electrical characteristics such as the output characteristic...Asymmetric doping channel (AC) partially depleted (PD) silicon-on-insulator (SOI) devices are simulated using two-dimensional simulation software. The electrical characteristics such as the output characteristics and the breakdown voltage are studied in detail. Through simulations,it is found that the AC PD SOI device can suppress the floating effects and improve the breakdown characteristics over conventional partially depleted silicon-on-insulator devices. Also compared to the reported AC FD SOI device,the performance variation with device parameters is more predictable and operable in industrial applications. The AC FD SO1 device has thinner silicon film, which causes parasitical effects such as coupling effects between the front gate and the back gate and hot electron degradation effects.展开更多
We present a novel, low-cost approach to fabricate flexible piezoelectric nano- generators (NGs) consisting of ZnO nanowires (NWs) on carbon fibers and foldable Au-coated ZnO NWs on paper. By using such designed s...We present a novel, low-cost approach to fabricate flexible piezoelectric nano- generators (NGs) consisting of ZnO nanowires (NWs) on carbon fibers and foldable Au-coated ZnO NWs on paper. By using such designed structure of the NGs, the radial ZnO NWs on a cylindrical fiber can be utilized fully and the electrical output of the NG is improved. The electrical output behavior of the NGs can be optionally controlled by increasing the fiber number, adjusting the strain rate and connection modes. For the single-fiber based NGs, the output voltage is 17 mV and the current density is about 0.09 μA·cm^-2, and the electrical output is enhanced greatly compared to that of previous similar micro-fiber based NGs. Compared with the single-fiber based NGs, the output current of the multi-fiber based NGs made of 200 carbon fibers increased 100-fold. An output voltage of 18 mV and current of 35 nA are generated from the multi-fiber based NGs. The electrical energy generated by the NGs is enough to power a practical device. The developed novel NGs can be used for smart textile structures, wearable and self-powered nanodevices.展开更多
文摘Asymmetric doping channel (AC) partially depleted (PD) silicon-on-insulator (SOI) devices are simulated using two-dimensional simulation software. The electrical characteristics such as the output characteristics and the breakdown voltage are studied in detail. Through simulations,it is found that the AC PD SOI device can suppress the floating effects and improve the breakdown characteristics over conventional partially depleted silicon-on-insulator devices. Also compared to the reported AC FD SOI device,the performance variation with device parameters is more predictable and operable in industrial applications. The AC FD SO1 device has thinner silicon film, which causes parasitical effects such as coupling effects between the front gate and the back gate and hot electron degradation effects.
基金AcknowledgementsThis work was supported by the National Major Research Program of China (No. 2013CB932602),the Major Project of International Cooperation and Exchanges (No. 2012DFA50990), the National Natural Science Foundation of China (NSFC) (Nos. 51172022, 51232001, and 51372020), the Fundamental Research Funds for Central Universities, the Program for New Century Excellent Talents in University, Beijing Higher Education Young Elite Teacher Project, the Programme of Introducing Talents of Discipline to Universities, and Program for Changjiang Scholars and Innovative Research Teams in University.
文摘We present a novel, low-cost approach to fabricate flexible piezoelectric nano- generators (NGs) consisting of ZnO nanowires (NWs) on carbon fibers and foldable Au-coated ZnO NWs on paper. By using such designed structure of the NGs, the radial ZnO NWs on a cylindrical fiber can be utilized fully and the electrical output of the NG is improved. The electrical output behavior of the NGs can be optionally controlled by increasing the fiber number, adjusting the strain rate and connection modes. For the single-fiber based NGs, the output voltage is 17 mV and the current density is about 0.09 μA·cm^-2, and the electrical output is enhanced greatly compared to that of previous similar micro-fiber based NGs. Compared with the single-fiber based NGs, the output current of the multi-fiber based NGs made of 200 carbon fibers increased 100-fold. An output voltage of 18 mV and current of 35 nA are generated from the multi-fiber based NGs. The electrical energy generated by the NGs is enough to power a practical device. The developed novel NGs can be used for smart textile structures, wearable and self-powered nanodevices.
