Performance of four-stage thermoelectric cooler for extended wavelength InGaAs detectors

Night vision applications utilize the reflected nightglow radiation in the short-wavelength infrared (SWIR) atmospheric window. Nevertheless, the low light intensity values require dark current densities on the order of n A / c m 2 for detection around room temperature. Currently, with new device architectures and developments in growth and surface passivation, very low dark current density values are achievable for 1.7 µm cutoff InGaAs detectors near room temperature, and such detectors seem to be the leading choice for the nightglow detection applications. On the other hand, HgCdTe has not been thoroughly investigated for low-cost nightglow detection with 1.7 µm cutoff, primarily due to its manufacture expenses for lattice-matched CdZnTe growth. In this study, we analyze the nightglow radiation detecting performance of the alternative substrate HgCdTe detectors near room temperature ( T = 270 K ) using computer simulations. It is assessed that alternative substrate HgCdTe cannot attain the required dark current density values due to Shockley–Read–Hall (SRH) recombination in the depletion region, if the heterojunction photodiode structure is adopted. To overcome the problem, depletion-engineered devices are designed where the depletion region is embedded within a larger bandgap HgCdTe, which suppresses the depletion region SRH ∼ 1300 times. This reduces the dark current density to the desired order, for SRH lifetimes achievable with alternative substrate growth. Dark current densities as low as 0.26 n A / c m 2 are shown to be possible for an SRH lifetime of τ = 3 µ s while maintaining the quantum efficiency ∼ 85 % . With this approach benefiting from alternative substrates and depletion engineering, HgCdTe can achieve InGaAs nightglow imaging performances near room temperature, and can benefit from less costly manufacture and broader application capability for nightglow radiation detection.

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SWIR nightglow radiation detection around room temperature with depletion-engineered HgCdTe on alternative substrates

Livanelioglu

Ozer

Kocaman

2019

J. Opt. Soc. Am. B

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Review of Short-Wavelength Infrared Flip-Chip Bump Bonding Process Technology

Du,

Zhao,

et al. 2025

Sensors

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Short-wave infrared (SWIR) imaging has a wide range of applications in civil and military fields. Over the past two decades, significant efforts have been devoted to developing high-resolution, high-sensitivity, and cost-effective SWIR sensors covering the spectral range from 0.9 μm to 3 μm. These advancements stimulate new prospects across a wide array of fields including life sciences, medical diagnostics, defense, surveillance, security, free-space optics (FSO), thermography, agriculture, food inspection, and LiDAR applications. In this review, we begin by introducing monolithic SWIR image sensors and hybrid SWIR image sensors and indicate that flip-chip bump bonding technology remains the predominant integration method for hybrid SWIR image sensors owing to its outstanding performance, adaptable integration with innovative epitaxial SWIR materials, long-term stability, and long-term reliability. Subsequently, we comprehensively summarize recent advancements in epitaxial thin-film SWIR sensors, encompassing FPAs and flip-chip bump bonding technology for epitaxial InGaAs and Ge (Sn) thin-film SWIR sensors. Finally, a summary and outlook regarding the development of InGaAs and Ge (Sn) SWIR sensors are provided and discussed. The ongoing evolution of epitaxial thin-film SWIR sensors with flip-chip bump bonding technology is poised to foster new applications in both academic and industry fields.

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Performance of four-stage thermoelectric cooler for extended wavelength InGaAs detectors

Cited by 2 publications

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SWIR nightglow radiation detection around room temperature with depletion-engineered HgCdTe on alternative substrates

SWIR nightglow radiation detection around room temperature with depletion-engineered HgCdTe on alternative substrates

Review of Short-Wavelength Infrared Flip-Chip Bump Bonding Process Technology

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