Effect of room air exposure on the field emission performance of UV light irradiated Si-gated field emitter arrays

IF 1.4 4区工程技术

Journal of Vacuum Science & Technology B Pub Date : 2022-01-01 DOI:10.1116/6.0001593

R. Bhattacharya, M. Cannon, R. Bhattacharjee, G. Rughoobur, N. Karaulac, W. Chern, A. Akinwande, J. Browning

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Abstract

Field emission cathodes are promising candidates in nanoscale vacuum channel transistors and are used in microwave vacuum electron devices. Prior research has shown that UV light exposure as well as 350 °C vacuum bake can desorb water vapor from Si field emission tips, resulting in lower work function and improved emission performance. However, after long exposure to room air (greater than 24 h), the improved performance is lost as water adsorbs on the tips. In this study, experiments were carried on two sets of 1000 × 1000 Si-gated field emitter arrays to determine the length of time that emitters can be exposed to room air without degradation. First, the samples were exposed to UV light irradiation in vacuum, and the I–V curves were measured. Then, the samples were exposed to room air with a relative humidity ranging from 30% to 40% for varying times (5, 6, 8, 12, 24, and 48 h) and then tested again under high vacuum. It was found that the emission current did not degrade after room air exposure of 5 h. However, at 6 h of exposure, degradation started to occur, and after 24 h, the emission current went back to the original, pre-UV exposure case. In a separate experiment, UV irradiated samples were stored in nitrogen for 72 h, with a 10% degradation in current. These results demonstrate that field emission devices with improved performance resulting from water desorption can be handled in air up to 5 h, depending upon humidity and stored in nitrogen for 72 h while maintaining improved performance. Published under an exclusive license by the AVS. https://doi.org/10.1116/6.0001593

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室内空气暴露对紫外光辐照硅门控场发射阵列场发射性能的影响

场发射阴极在纳米级真空通道晶体管和微波真空电子器件中都有很好的应用前景。先前的研究表明，紫外线照射和350°C真空烘烤可以解吸Si场发射尖端的水蒸气，从而降低功函数，提高发射性能。然而，在长时间暴露于室内空气(大于24小时)后，由于水吸附在尖端上，改善的性能就会丧失。在本研究中，对两组1000 × 1000硅门控场发射极阵列进行了实验，以确定发射极暴露在室内空气中而不降解的时间长度。首先，将样品置于真空紫外光照射下，测量样品的I-V曲线。然后，将样品暴露在相对湿度为30%至40%的室内空气中不同时间(5、6、8、12、24和48小时)，然后在高真空下再次进行测试。我们发现，在室内空气暴露5小时后，发射电流并没有降低。然而，在暴露6小时时，发射电流开始降低，24小时后，发射电流又恢复到紫外线暴露前的原始情况。在另一项实验中，紫外线照射后的样品在氮气中保存72小时，电流降解10%。这些结果表明，由于解吸水而提高性能的场发射装置可以在空气中处理长达5小时，具体取决于湿度，并在氮气中储存72小时，同时保持改进的性能。由AVS独家授权出版。https://doi.org/10.1116/6.0001593

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来源期刊

Journal of Vacuum Science & Technology B 工程技术-工程：电子与电气

自引率

14.30%

发文量

审稿时长

2.5 months

期刊介绍： Journal of Vacuum Science & Technology B emphasizes processing, measurement and phenomena associated with micrometer and nanometer structures and devices. Processing may include vacuum processing, plasma processing and microlithography among others, while measurement refers to a wide range of materials and device characterization methods for understanding the physics and chemistry of submicron and nanometer structures and devices.