用于室温氢探测的铂装饰钯纳米线

Abhishek Kumar, Yaoli Zhao, Sadaf Mohsenifard, Vaishali Maheshkar, Thomas Thundat, Mark T. Swihart
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引用次数: 0

摘要

使用氢作为能源载体需要低成本、低功耗的氢传感器。为了实现这一目标,我们合成了五孪晶钯纳米线(Pd NWs),并通过滴铸方法将其制成了传感器。将钯纳米线滴铸到互斥电极(IDE)上可产生 0.3% 至 1 vol.% H2 的响应,响应时间和恢复时间分别为 12 秒和 20 秒。然而,在低浓度 H2 时,它们表现出负响应(电阻下降)。纸基底上的钯碳纳米管对 1 vol.% H2 的响应提高了十倍,响应和恢复时间分别为 10 秒,但在低 H2 浓度时仍表现出负响应。将纸基钯碳氧化物传感器暴露在产生臭氧的紫外线下,会使钯碳氧化物合成过程中使用的 PVP 降解,从而消除反向感应反应,对 1 Vol.% H2 的响应为 5%,响应和恢复时间均为 15 秒。最后,通过催化 H2 解离,在钯碳氮化物上镀上少量铂(5%),可将响应和恢复时间缩短至 5 秒。这项工作为低成本传感器提供了一条途径,使人们能够安全地将 H2 用作能量载体。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Platinum Decorated Palladium Nanowires for Room-Temperature Hydrogen Detection

Platinum Decorated Palladium Nanowires for Room-Temperature Hydrogen Detection

The use of hydrogen as an energy carrier will require low-cost, low-power hydrogen sensors. Toward this goal, penta-twinned palladium nanowires (Pd NWs) are synthesized and fabricated sensors from them by drop-casting. Pd NWs drop-cast onto an interdigitated electrode (IDE) gave a response of 0.3% to 1 vol.% H2, with response and recovery times of 12 and 20 s, respectively. However, they exhibited a negative response (decreased resistance) at low H2 concentrations. Pd NWs on a paper substrate provided a tenfold higher response to 1 vol.% H2, with response and recovery times of 10 s each, but still exhibited negative response at low H2 concentration. Exposing the Pd NW-on-paper sensor to ozone-generating UV light degraded the PVP used in Pd NW synthesis, eliminating the reverse sensing response, and providing a response of 5% to 1 vol.% H2, with response and recovery times of 15 s. This allowed reliable H2 detection down to 100 ppm H2. Finally, coating the Pd NWs with a small amount of Pt (<5%) reduced the response and recovery times to 5 s by catalyzing H2 dissociation. This work provides a path to low-cost sensors to enable the safe use of H2 as an energy carrier.

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