Characterization of a Longwave HgCdTe GeoSnap Detector

Rory Bowens; Michael R. Meyer; Taylor L. Tobin; Eric Viges; Dennis Hart; John Monnier; Jarron Leisenring; Derek Ives; Roy van Boekel

doi:10.1117/12.3018499

Characterization of a Longwave HgCdTe GeoSnap Detector

Rory Bowens, Michael R. Meyer, Taylor L. Tobin, Eric Viges, Dennis Hart, John Monnier, Jarron Leisenring, Derek Ives, Roy van Boekel

Steward Observatory

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

1 Scopus citations

Abstract

New longwave HgCdTe detectors are critical to upcoming plans for ground-based infrared astronomy. These detectors, with fast-readouts and deep well-depths, will be key components of extremely large telescope instruments and therefore must be well understood prior to deployment. We analyze one such HgCdTe detector, a Teledyne Imaging Sensors GeoSnap, at the University of Michigan. We find that the properties of the GeoSnap are consistent with expectations from analysis of past devices. The GeoSnap has a well-depth of 2.75 million electrons per pixel, a read noise of 360 e-/pix, and a dark current of 330, 000 e-/s/pix at 45 K. The device experiences 1/f noise which can be mitigated relative to half-well shot noise with modest frequency image differencing. The GeoSnap’s quantum efficiency is calculated to be 79.7 ± 8.3 % at 10.6 microns. Although the GeoSnap’s bad pixel fraction, on the order of 3%, is consistent with other GeoSnap devices, close to a third of the bad pixels in this detector are clustered in a series of 31”leopard” spots spread across the detector plane. We report these properties and identify additional analyses that will be performed on future GeoSnap detectors.

Original language	English (US)
Title of host publication	X-Ray, Optical, and Infrared Detectors for Astronomy XI
Editors	Andrew D. Holland, Kyriaki Minoglou
Publisher	SPIE
ISBN (Electronic)	9781510675292
DOIs	https://doi.org/10.1117/12.3018499
State	Published - 2024
Event	X-Ray, Optical, and Infrared Detectors for Astronomy XI 2024 - Yokohama, Japan Duration: Jun 16 2024 → Jun 20 2024

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	13103
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	X-Ray, Optical, and Infrared Detectors for Astronomy XI 2024
Country/Territory	Japan
City	Yokohama
Period	6/16/24 → 6/20/24

Keywords

ELT
Infrared
Instrumentation

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Computer Science Applications
Applied Mathematics
Electrical and Electronic Engineering

Access to Document

10.1117/12.3018499

Cite this

Bowens, R., Meyer, M. R., Tobin, T. L., Viges, E., Hart, D., Monnier, J., Leisenring, J., Ives, D., & van Boekel, R. (2024). Characterization of a Longwave HgCdTe GeoSnap Detector. In A. D. Holland, & K. Minoglou (Eds.), X-Ray, Optical, and Infrared Detectors for Astronomy XI Article 1310325 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13103). SPIE. https://doi.org/10.1117/12.3018499

Characterization of a Longwave HgCdTe GeoSnap Detector. / Bowens, Rory; Meyer, Michael R.; Tobin, Taylor L. et al.
X-Ray, Optical, and Infrared Detectors for Astronomy XI. ed. / Andrew D. Holland; Kyriaki Minoglou. SPIE, 2024. 1310325 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13103).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Bowens, R, Meyer, MR, Tobin, TL, Viges, E, Hart, D, Monnier, J, Leisenring, J, Ives, D & van Boekel, R 2024, Characterization of a Longwave HgCdTe GeoSnap Detector. in AD Holland & K Minoglou (eds), X-Ray, Optical, and Infrared Detectors for Astronomy XI., 1310325, Proceedings of SPIE - The International Society for Optical Engineering, vol. 13103, SPIE, X-Ray, Optical, and Infrared Detectors for Astronomy XI 2024, Yokohama, Japan, 6/16/24. https://doi.org/10.1117/12.3018499

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abstract = "New longwave HgCdTe detectors are critical to upcoming plans for ground-based infrared astronomy. These detectors, with fast-readouts and deep well-depths, will be key components of extremely large telescope instruments and therefore must be well understood prior to deployment. We analyze one such HgCdTe detector, a Teledyne Imaging Sensors GeoSnap, at the University of Michigan. We find that the properties of the GeoSnap are consistent with expectations from analysis of past devices. The GeoSnap has a well-depth of 2.75 million electrons per pixel, a read noise of 360 e-/pix, and a dark current of 330, 000 e-/s/pix at 45 K. The device experiences 1/f noise which can be mitigated relative to half-well shot noise with modest frequency image differencing. The GeoSnap{\textquoteright}s quantum efficiency is calculated to be 79.7 ± 8.3 % at 10.6 microns. Although the GeoSnap{\textquoteright}s bad pixel fraction, on the order of 3%, is consistent with other GeoSnap devices, close to a third of the bad pixels in this detector are clustered in a series of 31”leopard” spots spread across the detector plane. We report these properties and identify additional analyses that will be performed on future GeoSnap detectors.",

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AB - New longwave HgCdTe detectors are critical to upcoming plans for ground-based infrared astronomy. These detectors, with fast-readouts and deep well-depths, will be key components of extremely large telescope instruments and therefore must be well understood prior to deployment. We analyze one such HgCdTe detector, a Teledyne Imaging Sensors GeoSnap, at the University of Michigan. We find that the properties of the GeoSnap are consistent with expectations from analysis of past devices. The GeoSnap has a well-depth of 2.75 million electrons per pixel, a read noise of 360 e-/pix, and a dark current of 330, 000 e-/s/pix at 45 K. The device experiences 1/f noise which can be mitigated relative to half-well shot noise with modest frequency image differencing. The GeoSnap’s quantum efficiency is calculated to be 79.7 ± 8.3 % at 10.6 microns. Although the GeoSnap’s bad pixel fraction, on the order of 3%, is consistent with other GeoSnap devices, close to a third of the bad pixels in this detector are clustered in a series of 31”leopard” spots spread across the detector plane. We report these properties and identify additional analyses that will be performed on future GeoSnap detectors.

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Characterization of a Longwave HgCdTe GeoSnap Detector

Abstract

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Keywords

ASJC Scopus subject areas

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