Hydrogen Loading System for Thin Films for Betavoltaics

IF 0.5 Q4 NUCLEAR SCIENCE & TECHNOLOGY
Darrell Cheu, Thomas Adams, Shripad T. Revankar
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引用次数: 0

Abstract

Abstract Betavoltaics are direct conversion energy devices that are ideal for low power and long-lasting, uninterruptable applications. Betavoltaics operate similarly to photovoltaics where a radio isotope irradiates beta particles into a semiconductor p-n junction that converts the kinetic energy into electrical energy. Betavoltaics are limited by their power output from the radio isotope. However, the source power density can be increased by the selection of solid-state substrates. While tritium absorbing substrates can be simulated to estimate tritium absorption levels and surface emission energies, their viability has to be physically evaluated. A state-of-the-art hydrogen loading system developed by our research group was used to evaluate different film types to understand how they perform during the hydrogen/tritium loading process. The hydrogen loading system utilizes the Sievert technique, where the temperature and volume is constant and pressure drop of the system is used to determine hydrogen uptake of a film substrate. The hydrogen loading system procedure was verified using 250 nm thick palladium films at three loading temperatures. Results clearly show uptake of hydrogen by the thin palladium films accurate to the ideal stoichiometric ratio of one hydrogen atom to host palladium atom.
光电薄膜氢负载系统
Betavoltaics是一种直接转换能量的设备,是低功耗、持久、不间断应用的理想选择。Betavoltaics的工作原理与光伏类似,其中放射性同位素将β粒子照射到半导体p-n结中,将动能转换为电能。betavoltaic受到来自放射性同位素的功率输出的限制。然而,可以通过选择固态衬底来增加源功率密度。虽然可以模拟氚吸收基质来估计氚吸收水平和表面发射能量,但它们的生存能力必须进行物理评估。我们的研究小组开发了一个最先进的氢加载系统,用于评估不同类型的薄膜,以了解它们在氢/氚加载过程中的表现。氢气装载系统采用Sievert技术,其中温度和体积是恒定的,系统的压降用于确定膜基板的氢气吸收率。在三种加载温度下,用250 nm厚的钯膜对氢气加载系统进行了验证。结果清楚地表明,薄钯膜对氢的吸收精确地达到一个氢原子与宿主钯原子的理想化学计量比。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
1.30
自引率
0.00%
发文量
56
期刊介绍: The Journal of Nuclear Engineering and Radiation Science is ASME’s latest title within the energy sector. The publication is for specialists in the nuclear/power engineering areas of industry, academia, and government.
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