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Proceedings Paper

ALD-microchannel plates for cryogenic applications (Conference Presentation)
Author(s): Till Cremer; Bernhard W. Adams; Melvin Aviles; Justin L. Bond; Christopher A. Craven; Michael R. Foley; Alexey Lyashenko; Michael J. Minot; Mark A. Popecki; Michael E. Stochaj; William A. Worstell; Jeffrey W. Elam; Anil U. Mane; Oswald H. W. Siegmund; Camden Ertley

Paper Abstract

Atomic layer deposition (ALD) has enabled the development of a new technology for fabricating microchannel plates (MCPs) with improved performance that offer transformative benefits to a wide variety of applications. Incom uses a “hollow-core” process for fabricating glass capillary array (GCA) plates consisting of millions of micrometer-sized glass microchannels fused together in a regular pattern. The resistive and secondary electron emissive (SEE) functions necessary for electron amplification are applied to the GCA microchannels by ALD, which – in contrast to conventional MCP manufacturing– enables independent tuning of both resistance and SEE to maximize and customize MCP performance. Incom is currently developing MCPs that operate at cryogenic temperatures and across wide temperature ranges. The resistive layers in both, conventional and ALD-MCPs, exhibit semiconductor-like behavior and therefore a negative thermal coefficient of resistance (TCR): when the MCP is cooled, the resistance increases, and when heated, the resistance drops. Consequently, the resistance of each MCP must be tailored for the intended operating temperature. This sensitivity to temperature changes presents a challenge for many terrestrial and space based applications. The resistivity of the ALD-nanocomposite material can be tuned over a wide range. The material’s (thermo-) electrical properties depend on film thickness, composition, nanostructure, and the chemical nature of the dielectric and metal components. We show how the structure-property relationships developed in this work can be used to design MCPs that operate reliably at cryogenic temperatures. We also present data on how the resistive material’s TCR characteristics can be improved to enable MCPs operating across wider temperature ranges than currently possible.

Paper Details

Date Published: 19 September 2017
Proc. SPIE 10397, UV, X-Ray, and Gamma-Ray Space Instrumentation for Astronomy XX, 103970Z (19 September 2017); doi: 10.1117/12.2277185
Show Author Affiliations
Till Cremer, Incom, Inc. (United States)
Bernhard W. Adams, Incom Inc. (United States)
Melvin Aviles, Incom Inc. (United States)
Justin L. Bond, Incom Inc. (United States)
Christopher A. Craven, Incom Inc. (United States)
Michael R. Foley, Incom Inc. (United States)
Alexey Lyashenko, Incom Inc. (United States)
Michael J. Minot, Incom Inc. (United States)
Mark A. Popecki, Incom, Inc. (United States)
Michael E. Stochaj, Incom, Inc. (United States)
William A. Worstell, Incom, Inc. (United States)
Jeffrey W. Elam, Argonne National Lab. (United States)
Anil U. Mane, Argonne National Lab. (United States)
Oswald H. W. Siegmund, Univ. of California, Berkeley (United States)
Camden Ertley, Univ. of California, Berkeley (United States)

Published in SPIE Proceedings Vol. 10397:
UV, X-Ray, and Gamma-Ray Space Instrumentation for Astronomy XX
Oswald H. Siegmund, Editor(s)

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