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Main Authors: Murros, Anton, Sovanto, Kuura, Tiira, Jonna, Tappura, Kirsi, Prunnila, Mika, Varpula, Aapo
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.05809
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author Murros, Anton
Sovanto, Kuura
Tiira, Jonna
Tappura, Kirsi
Prunnila, Mika
Varpula, Aapo
author_facet Murros, Anton
Sovanto, Kuura
Tiira, Jonna
Tappura, Kirsi
Prunnila, Mika
Varpula, Aapo
contents State-of the-art infrared photodetectors operating in the mid- and long-wavelength infrared (MWIR and LWIR) are largely dominated by cryogenically cooled quantum sensors when the target is the highest sensitivity and detection speeds. Nano-thermoelectrics provide a route towards competitive uncooled infrared bolometer technology that can obtain high speed and sensitivity, low-power operation, and cost-effectiveness. We demonstrate nano-thermoelectric LWIR bolometers with fast and high-sensitivity response to LWIR around 10 $μ$m. These devices are based on ultra-thin silicon membranes that utilize the dimensional scaling of silicon nanomembranes in thermoelectric elements and are combined with metallic nanomembranes with subwavelength absorber structures. The fast device performance stems from a low heat capacity design where the thermoelectric beams act both as mechanical supports and transducer elements. Furthermore, by scaling down the thickness of the thermoelectric beams the thermal conductivity is reduced owing to enhanced phonon boundary scattering, resulting in increased sensitivity. The nano-thermoelectric LWIR bolometers are based on 40-nm-thick n- and p-type silicon membranes with LWIR (voltage) responsivities up to 1636 V/W and 1350 V/W and time constants in the range of 300-600 $μ$s, resulting in specific detectivities up to $1.56\times10^8$ cmHz$^{1/2}$/W. We also investigate the use of a heavily doped N++ substrate to increase optical cavity back reflection, resulting in an increased Si substrate reflectance from 30% to 70%-75% for wavelengths between 8-10 $μ$m, resulting in an increase in device responsivity by approximately 20%.
format Preprint
id arxiv_https___arxiv_org_abs_2410_05809
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Infrared Bolometers Based on 40-nm-Thick Nano-Thermoelectric Silicon Membranes
Murros, Anton
Sovanto, Kuura
Tiira, Jonna
Tappura, Kirsi
Prunnila, Mika
Varpula, Aapo
Optics
Applied Physics
Instrumentation and Detectors
State-of the-art infrared photodetectors operating in the mid- and long-wavelength infrared (MWIR and LWIR) are largely dominated by cryogenically cooled quantum sensors when the target is the highest sensitivity and detection speeds. Nano-thermoelectrics provide a route towards competitive uncooled infrared bolometer technology that can obtain high speed and sensitivity, low-power operation, and cost-effectiveness. We demonstrate nano-thermoelectric LWIR bolometers with fast and high-sensitivity response to LWIR around 10 $μ$m. These devices are based on ultra-thin silicon membranes that utilize the dimensional scaling of silicon nanomembranes in thermoelectric elements and are combined with metallic nanomembranes with subwavelength absorber structures. The fast device performance stems from a low heat capacity design where the thermoelectric beams act both as mechanical supports and transducer elements. Furthermore, by scaling down the thickness of the thermoelectric beams the thermal conductivity is reduced owing to enhanced phonon boundary scattering, resulting in increased sensitivity. The nano-thermoelectric LWIR bolometers are based on 40-nm-thick n- and p-type silicon membranes with LWIR (voltage) responsivities up to 1636 V/W and 1350 V/W and time constants in the range of 300-600 $μ$s, resulting in specific detectivities up to $1.56\times10^8$ cmHz$^{1/2}$/W. We also investigate the use of a heavily doped N++ substrate to increase optical cavity back reflection, resulting in an increased Si substrate reflectance from 30% to 70%-75% for wavelengths between 8-10 $μ$m, resulting in an increase in device responsivity by approximately 20%.
title Infrared Bolometers Based on 40-nm-Thick Nano-Thermoelectric Silicon Membranes
topic Optics
Applied Physics
Instrumentation and Detectors
url https://arxiv.org/abs/2410.05809