The ongoing advanced space exploration requires the novel energy sources that can generate power for extreme duration without need of refill. The long duration betavoltaic devices are presented using conjugated polymer with scintilla-tors. The Monte Carlo simulations are used to study the interaction of electron beam with two different scintillators, Cerium doped Yttrium Aluminum Garnet (Ce:YAG) and Thallium doped Cesium Iodide (CsI:Tl). The catholuminescence profiles from simulation showed that CsI.Tl is more-efficient to generate photons when hit by electron beam compared to Ce:YAG. The semiconductive conjugated polymer device stack of ITO/PED0T:PSS/P3HT:ICBA/Al are then fabricated and tested with Ce.YAG and CsI.Tl scintillators under different electron beam energies. The electrical current is successfully extracted from these betavoltaic devices when illuminated with electron beams. As expected, the betavoltaic devices with CsI.Tl scin-tillator performed better compared with Ce.YAG. The maximum power conversion efficiency (PCE) of 0.24% is obtained at 10 kV electron beam with CsI:Tl, while PCE in device with Ce:YAG is 0.16%. The short circuit current in devices with CsI.Tl is about 57%, greater than in devices with Ce.YAG. The experimental result showed that output electrical power increased with increase in incident electron beam energy.
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机译:正在进行的高级空间探索需要新颖的能源,可以在不需要补充的情况下产生极端持续时间的功率。使用缀合的聚合物与闪烁液相色的聚合物呈现长时间的贝虫装置。 Monte Carlo模拟用于研究电子束与两个不同的闪烁体的相互作用,铈掺杂钇铝石榴石(Ce:YAG)和铊掺杂铯碘化物(CSI:T1)。仿真的致孔发光谱表明,与CE:YAG相比,通过电子束击中时,CSI.TL更有效地产生光子。 ITO / PED0T:PSS / P3HT:ICBA / Al的半导体缀合聚合物装置堆叠,然后用Ce.yag和CSI.TL闪烁体在不同的电子束能下进行制造和测试。当用电子束照射时,电流从这些贝榫件成功提取。正如预期的那样,与CSI.YAG相比,使用CSI.TL Scin-Timator的BetaVoltaic装置表现出更好。 0.24%的最大功率转换效率(PCE)在10 kV电子束,CSI:TL获得,而具有CE:YAG的装置中的PCE为0.16%。具有CSI.TL的设备中的短路电流约为57%,大于使用CE.yAG的设备。实验结果表明,输出电力随着入射电子束能量的增加而增加。
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