Single Photon Counting UV Solar-Blind Detectors Using Silicon and III-Nitride Materials

Ultraviolet (UV) studies in astronomy, cosmology, planetary studies, biological and medical applications often require precision detection of faint objects and in many cases require photon-counting detection. We present an overview of two approaches for achieving photon counting in the UV. The first...

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Autores principales: Nikzad, Shouleh, Hoenk, Michael, Jewell, April D., Hennessy, John J., Carver, Alexander G., Jones, Todd J., Goodsall, Timothy M., Hamden, Erika T., Suvarna, Puneet, Bulmer, J., Shahedipour-Sandvik, F., Charbon, Edoardo, Padmanabhan, Preethi, Hancock, Bruce, Bell, L. Douglas
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2016
Materias:
Review
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4934352/
https://www.ncbi.nlm.nih.gov/pubmed/27338399
http://dx.doi.org/10.3390/s16060927
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author Nikzad, Shouleh
Hoenk, Michael
Jewell, April D.
Hennessy, John J.
Carver, Alexander G.
Jones, Todd J.
Goodsall, Timothy M.
Hamden, Erika T.
Suvarna, Puneet
Bulmer, J.
Shahedipour-Sandvik, F.
Charbon, Edoardo
Padmanabhan, Preethi
Hancock, Bruce
Bell, L. Douglas
author_facet Nikzad, Shouleh
Hoenk, Michael
Jewell, April D.
Hennessy, John J.
Carver, Alexander G.
Jones, Todd J.
Goodsall, Timothy M.
Hamden, Erika T.
Suvarna, Puneet
Bulmer, J.
Shahedipour-Sandvik, F.
Charbon, Edoardo
Padmanabhan, Preethi
Hancock, Bruce
Bell, L. Douglas
author_sort Nikzad, Shouleh
collection PubMed
description Ultraviolet (UV) studies in astronomy, cosmology, planetary studies, biological and medical applications often require precision detection of faint objects and in many cases require photon-counting detection. We present an overview of two approaches for achieving photon counting in the UV. The first approach involves UV enhancement of photon-counting silicon detectors, including electron multiplying charge-coupled devices and avalanche photodiodes. The approach used here employs molecular beam epitaxy for delta doping and superlattice doping for surface passivation and high UV quantum efficiency. Additional UV enhancements include antireflection (AR) and solar-blind UV bandpass coatings prepared by atomic layer deposition. Quantum efficiency (QE) measurements show QE > 50% in the 100–300 nm range for detectors with simple AR coatings, and QE ≅ 80% at ~206 nm has been shown when more complex AR coatings are used. The second approach is based on avalanche photodiodes in III-nitride materials with high QE and intrinsic solar blindness.
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spelling pubmed-49343522016-07-06 Single Photon Counting UV Solar-Blind Detectors Using Silicon and III-Nitride Materials Nikzad, Shouleh Hoenk, Michael Jewell, April D. Hennessy, John J. Carver, Alexander G. Jones, Todd J. Goodsall, Timothy M. Hamden, Erika T. Suvarna, Puneet Bulmer, J. Shahedipour-Sandvik, F. Charbon, Edoardo Padmanabhan, Preethi Hancock, Bruce Bell, L. Douglas Sensors (Basel) Review Ultraviolet (UV) studies in astronomy, cosmology, planetary studies, biological and medical applications often require precision detection of faint objects and in many cases require photon-counting detection. We present an overview of two approaches for achieving photon counting in the UV. The first approach involves UV enhancement of photon-counting silicon detectors, including electron multiplying charge-coupled devices and avalanche photodiodes. The approach used here employs molecular beam epitaxy for delta doping and superlattice doping for surface passivation and high UV quantum efficiency. Additional UV enhancements include antireflection (AR) and solar-blind UV bandpass coatings prepared by atomic layer deposition. Quantum efficiency (QE) measurements show QE > 50% in the 100–300 nm range for detectors with simple AR coatings, and QE ≅ 80% at ~206 nm has been shown when more complex AR coatings are used. The second approach is based on avalanche photodiodes in III-nitride materials with high QE and intrinsic solar blindness. MDPI 2016-06-21 /pmc/articles/PMC4934352/ /pubmed/27338399 http://dx.doi.org/10.3390/s16060927 Text en © 2016 by the authors; licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC-BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Review
Nikzad, Shouleh
Hoenk, Michael
Jewell, April D.
Hennessy, John J.
Carver, Alexander G.
Jones, Todd J.
Goodsall, Timothy M.
Hamden, Erika T.
Suvarna, Puneet
Bulmer, J.
Shahedipour-Sandvik, F.
Charbon, Edoardo
Padmanabhan, Preethi
Hancock, Bruce
Bell, L. Douglas
Single Photon Counting UV Solar-Blind Detectors Using Silicon and III-Nitride Materials
title Single Photon Counting UV Solar-Blind Detectors Using Silicon and III-Nitride Materials
title_full Single Photon Counting UV Solar-Blind Detectors Using Silicon and III-Nitride Materials
title_fullStr Single Photon Counting UV Solar-Blind Detectors Using Silicon and III-Nitride Materials
title_full_unstemmed Single Photon Counting UV Solar-Blind Detectors Using Silicon and III-Nitride Materials
title_short Single Photon Counting UV Solar-Blind Detectors Using Silicon and III-Nitride Materials
title_sort single photon counting uv solar-blind detectors using silicon and iii-nitride materials
topic Review
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4934352/
https://www.ncbi.nlm.nih.gov/pubmed/27338399
http://dx.doi.org/10.3390/s16060927
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