Quantitative Field Emission Imaging for Studying the Doping-Dependent Emission Behavior of Silicon Field Emitter Arrays

Schels, Andreas; Herdl, Florian; Hausladen, Matthias; Wohlfartsstätter, Dominik; Edler, Simon; Bachmann, Michael; Pahlke, Andreas; Schreiner, Rupert; Hansch, Walter

doi:10.3390/mi14112008

Micromachines

2023

DOI: 10.3390/mi14112008

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Quantitative Field Emission Imaging for Studying the Doping-Dependent Emission Behavior of Silicon Field Emitter Arrays

Andreas Schels,

Florian Herdl,

Matthias Hausladen

et al.

Abstract: Field emitter arrays (FEAs) are a promising component for novel vacuum micro- and nanoelectronic devices, such as microwave power amplifiers or fast-switching X-ray sources. However, the interrelated mechanisms responsible for FEA degradation and failure are not fully understood. Therefore, we present a measurement method for quantitative observation of individual emission sites during integral operation using a low-cost, commercially available CMOS imaging sensor. The emission and degradation behavior of thre… Show more

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2024

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Cited by 2 publications

References 54 publications

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High current field emission from Si nanowires on pillar structures

Buchner,

Hausladen,

Bartl

et al. 2024

Journal of Vacuum Science &Amp; Technology B

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We investigate the influence of the geometry and doping level on the performance of n-type silicon nanowire field emitters on silicon pillar structures. Therefore, multiple cathodes with 50 by 50 pillar arrays (diameter: 5 μm, height: 30 μm, spacing: 50 μm) were fabricated and measured in diode configuration. In the first experiment, we compared two geometry types using the same material. Geometry 1 is black silicon, which is a highly dense surface covering a forest of tightly spaced silicon needles resulting from self-masking during a plasma etching process of single crystal silicon. Geometry 2 are silicon nanowires, which are individual spaced-out nanowires in a crownlike shape resulting from a plasma etching process of single crystal silicon. In the second experiment, we compared two different silicon doping levels [n-type (P), 1–10 and <0.005 Ω cm] for the same geometry. The best performance was achieved with lower doped silicon nanowire samples, emitting 2 mA at an extraction voltage of 1 kV. The geometry/material combination with the best performance was used to assemble an integrated electron source. These electron sources were measured in a triode configuration and reached onset voltages of about 125 V and emission currents of 2.5 mA at extraction voltages of 400 V, while achieving electron transmission rates as high as 85.0%.

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High current field emission from Si nanowires on pillar structures

Buchner,

Hausladen,

Bartl

et al. 2024

Journal of Vacuum Science &Amp; Technology B

View full text Add to dashboard Cite

show abstract

Measurement of field emission array current distributions by metal-coated CMOS image sensors

Hausladen,

Schels,

Buchner

et al. 2024

Journal of Vacuum Science &Amp; Technology B

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A CMOS image sensor is utilized to determine the time- and spatially resolved distribution of the total electron emission current of a silicon field emission array. The sensor measures electron emission without the need for phosphorus screens or scintillators as converters. However, in initial experiments, rather low field emission currents of several hundreds of nanoamperes per emitter already damaged the sensor surface, which altered the systems’ signal response over the measurement time. In consequence, we coated the CMOS sensor surface with a Cu layer for surface protection. In contrast to the original insulating surface, Cu is an excellent current- and heat-conductor, which avoids lens charging by providing a conductive path for incident electrons and has an improved heat dissipation capability. Measurements using a segmented field emission cathode with four individually addressable tips demonstrate a consistent correlation between the emission current and the sensor signal of the metal-coated image sensor. Furthermore, the characterization of a field emission array showed that single tip emission currents of up to 12 μA per tip are measurable without discernible damage effects of the sensor’s surface.

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Quantitative Field Emission Imaging for Studying the Doping-Dependent Emission Behavior of Silicon Field Emitter Arrays

Cited by 2 publications

References 54 publications

High current field emission from Si nanowires on pillar structures

High current field emission from Si nanowires on pillar structures

Measurement of field emission array current distributions by metal-coated CMOS image sensors

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