Standard

Effect of CdTe layer thickness on multimode optical thermometry for cryogenic temperatures. / Борисов, Евгений Вадимович; Калиничев, Алексей Андреевич; Колесников, Илья Евгеньевич.

In: Journal of Luminescence, Vol. 285, 121317, 10.2025.

Research output: Contribution to journalArticlepeer-review

Harvard

Борисов, ЕВ, Калиничев, АА & Колесников, ИЕ 2025, 'Effect of CdTe layer thickness on multimode optical thermometry for cryogenic temperatures', Journal of Luminescence, vol. 285, 121317. https://doi.org/10.1016/j.jlumin.2025.121317

APA

Борисов, Е. В., Калиничев, А. А., & Колесников, И. Е. (2025). Effect of CdTe layer thickness on multimode optical thermometry for cryogenic temperatures. Journal of Luminescence, 285, [121317]. https://doi.org/10.1016/j.jlumin.2025.121317

Vancouver

Борисов ЕВ, Калиничев АА, Колесников ИЕ. Effect of CdTe layer thickness on multimode optical thermometry for cryogenic temperatures. Journal of Luminescence. 2025 Oct;285. 121317. https://doi.org/10.1016/j.jlumin.2025.121317

Author

Борисов, Евгений Вадимович ; Калиничев, Алексей Андреевич ; Колесников, Илья Евгеньевич. / Effect of CdTe layer thickness on multimode optical thermometry for cryogenic temperatures. In: Journal of Luminescence. 2025 ; Vol. 285.

BibTeX

@article{507bce403be14d4fbbdab0e231e05f1f,
title = "Effect of CdTe layer thickness on multimode optical thermometry for cryogenic temperatures",
abstract = "Traditional contact thermometry faces a lot of challenges in the cryogenic temperature range. Remote temperature sensing techniques, especially optical thermometry, offering fast response, high spatial and temperature resolution could be a promising solution. Here, ZnTe/CdTe nanostructures with different CdTe layer thicknesses were tested as multimode temperature sensors in the cryogenic range of 20–70 K. The temperature reading was provided by monitoring LIR, spectral position, bandwidth, and energy gap, which enhances the reliability of thermometry. The effect of CdTe layer thickness was studied in terms of thermometric performances. The best thermal sensitivity of 9.8 % K−1@20K was achieved using the energy gap, while the minimum temperature resolution of 0.2 K@20K was obtained using the spectral position. Despite the better thermometric performance of the 1 ML sample, the 2 ML sample offers a wider choice of temperature-sensitive parameters for optical thermometry, making it more versatile.",
keywords = "CdTe, Cryogenic temperature, Multimode thermometry, Optical thermometry, Reflectance, ZnTe",
author = "Борисов, {Евгений Вадимович} and Калиничев, {Алексей Андреевич} and Колесников, {Илья Евгеньевич}",
year = "2025",
month = oct,
doi = "10.1016/j.jlumin.2025.121317",
language = "English",
volume = "285",
journal = "Journal of Luminescence",
issn = "0022-2313",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Effect of CdTe layer thickness on multimode optical thermometry for cryogenic temperatures

AU - Борисов, Евгений Вадимович

AU - Калиничев, Алексей Андреевич

AU - Колесников, Илья Евгеньевич

PY - 2025/10

Y1 - 2025/10

N2 - Traditional contact thermometry faces a lot of challenges in the cryogenic temperature range. Remote temperature sensing techniques, especially optical thermometry, offering fast response, high spatial and temperature resolution could be a promising solution. Here, ZnTe/CdTe nanostructures with different CdTe layer thicknesses were tested as multimode temperature sensors in the cryogenic range of 20–70 K. The temperature reading was provided by monitoring LIR, spectral position, bandwidth, and energy gap, which enhances the reliability of thermometry. The effect of CdTe layer thickness was studied in terms of thermometric performances. The best thermal sensitivity of 9.8 % K−1@20K was achieved using the energy gap, while the minimum temperature resolution of 0.2 K@20K was obtained using the spectral position. Despite the better thermometric performance of the 1 ML sample, the 2 ML sample offers a wider choice of temperature-sensitive parameters for optical thermometry, making it more versatile.

AB - Traditional contact thermometry faces a lot of challenges in the cryogenic temperature range. Remote temperature sensing techniques, especially optical thermometry, offering fast response, high spatial and temperature resolution could be a promising solution. Here, ZnTe/CdTe nanostructures with different CdTe layer thicknesses were tested as multimode temperature sensors in the cryogenic range of 20–70 K. The temperature reading was provided by monitoring LIR, spectral position, bandwidth, and energy gap, which enhances the reliability of thermometry. The effect of CdTe layer thickness was studied in terms of thermometric performances. The best thermal sensitivity of 9.8 % K−1@20K was achieved using the energy gap, while the minimum temperature resolution of 0.2 K@20K was obtained using the spectral position. Despite the better thermometric performance of the 1 ML sample, the 2 ML sample offers a wider choice of temperature-sensitive parameters for optical thermometry, making it more versatile.

KW - CdTe

KW - Cryogenic temperature

KW - Multimode thermometry

KW - Optical thermometry

KW - Reflectance

KW - ZnTe

UR - https://www.mendeley.com/catalogue/8978c71b-e26b-37a9-a72a-9fd2c8969b74/

U2 - 10.1016/j.jlumin.2025.121317

DO - 10.1016/j.jlumin.2025.121317

M3 - Article

VL - 285

JO - Journal of Luminescence

JF - Journal of Luminescence

SN - 0022-2313

M1 - 121317

ER -

ID: 136063188