Highly sensitive and efficient 1550 nm photodetector for room temperature operation

Rituraj ¹

Zhi-Gang Yu ²

R. M. E. B. Kandegedara ³

Shanhui Fan ⁴

Srinivasan Krishnamurthy ^{2, 3}

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Department of Electrical Engineering, Indian Institute of Technology Kanpur 1 , Kanpur, U.P. 208016, |

Sivananthan Laboratories 2 , Bolingbrook, Illinois 60440,

Microphysics Laboratory, University of Illinois at Chicago 3 , Chicago, Illinois 60607, |

⁴

Department of Applied Physics, Stanford University 4 , Stanford, California 94305, |

Publication type: Journal Article

Publication date: 2025-01-01

AIP Publishing

Journal: AIP Advances

scimago Q3

SJR: 0.337

CiteScore: 2.8

Impact factor: 1.4

ISSN: 21583226

DOI: 10.1063/5.0238863

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Abstract

Photonic quantum technologies such as effective quantum communication require room temperature (RT) operating single- or few-photon sensors with high external quantum efficiency (EQE) at 1550 nm wavelength. The leading class of devices in this segment is avalanche photodetectors operating particularly in the Geiger mode. However, for superior performance, a trade-off has to be made between temperature of operation, device thickness, and EQE. Two-dimensional (2D) materials can be used to reduce the absorber thickness and thus dark current, leading to an increase in the operating temperature, but they suffer from low EQE. We use specifically stacked bilayer hexagonal BAs, with material properties calculated from first principles, on a co-optimized dielectric photonic crystal substrate to simultaneously decrease the dark current by three orders of magnitude at RT and maintain an EQE of >99%. The device can potentially be used in avalanche mode and hence can form a basis for single photon detection.