Integrated multichip field emission electron source fabricated by laser-micromachining and MEMS technology

M. Hausladen, P. Buchner, M. Bartl, M. Bachmann, R. Schreiner
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Abstract

In this work, high-current field emission electron source chips were fabricated using laser-micromachining and MEMS technology. The resulting chips were combined with commercially available printed circuit boards (PCBs) to obtain a multichip electron source. By controlling the separate electron sources using an external current control circuit, we were able to divide the desired total current evenly across the individual chips deployed in the PCB-carrier. In consequence, we were able to show a decreased degradation due to the reduced current load per chip. First, a single electron source chip was measured without current regulation. A steady-state emission current of 1 mA with a high stability of ±1.3% at an extraction voltage of 250 V was observed. At this current level, a mean degradation slope of −0.7 μA/min with a nearly perfect transmission ratio of 99% ± 0.4% was determined. The measurements of a fully assembled multichip PCB-carrier electron source, using a current control circuit for regulation, showed that an even distribution of the desired total current led to a decreased degradation. This was determined by the increase in the required extraction voltage over time. For this purpose, two current levels were applied to the electron source chips of the PCB-carrier using an external current control circuit. First, 300 μA total current was evenly distributed among the individual electron source chips followed by the emission of 300 μA per electron source chip. This allows the observation of the influence of a distributed and nondistributed total current, carried by the electron source chips. Thereby, we obtained an increase in the mean degradation slope from +0.011 V/min (300 μA distributed) to +0.239 V/min (300 μA per chip), which is approximately 21 times higher. Moreover, our current control circuit improved the current stability to under 0.1% for both current levels, 300 μA distributed and 300 μA per chip.
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利用激光微机械加工和微机电系统技术制造的集成多芯片场发射电子源
在这项工作中,利用激光微加工和微机电系统技术制造了大电流场发射电子源芯片。将制作出的芯片与市场上销售的印刷电路板(PCB)相结合,就得到了多芯片电子源。通过使用外部电流控制电路来控制独立的电子源,我们能够将所需的总电流平均分配给印刷电路板载体中的各个芯片。因此,由于减少了每个芯片的电流负载,我们能够显示出衰减的减少。首先,在没有电流调节的情况下对单个电子源芯片进行了测量。在提取电压为 250 V 时,稳态发射电流为 1 mA,稳定性高达 ±1.3%。在此电流水平下,平均衰减斜率为-0.7 μA/min,透射比接近完美,为 99% ± 0.4%。使用电流控制电路对完全组装好的多芯片 PCB 载流子电子源进行的测量表明,均匀分布所需的总电流可降低衰减。这是由所需提取电压随时间推移而增加所决定的。为此,使用外部电流控制电路对 PCB 载波的电子源芯片施加了两个电流等级。首先,300 μA 的总电流在各个电子源芯片之间均匀分布,然后每个电子源芯片发射 300 μA 的电流。这样就可以观察到电子源芯片所携带的分布式和非分布式总电流的影响。因此,我们得到的平均衰减斜率从 +0.011 V/min(300 μA 分布)增加到 +0.239 V/min(每个芯片 300 μA),大约增加了 21 倍。此外,我们的电流控制电路还将分布式 300 μA 和单芯片 300 μA 两种电流水平的电流稳定性提高到 0.1% 以下。
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