Thermal Isolation Through Nanostructuring

David Leadley; Vishal Shah; Jouni Ahopelto; Francesc Alzina; Emigdio Chávez-Ángel; Juha Muhonen; Maksym Myronov; Androula G. Nassiopoulou; Hung Nguyen; Evan Parker; Jukka Pekola; Martin Prest; Mika Prunnila; Juan Sebastian Reparaz; Andrey Shchepetov; Clivia Sotomayor-Torres; Katerina Valalaki; Terry Whall

doi:10.1002/9781118984772.ch12

Thermal Isolation Through Nanostructuring

David Leadley, Vishal Shah, Jouni Ahopelto, Francesc Alzina, Emigdio Chávez-Ángel, Juha Muhonen, Maksym Myronov, Androula G. Nassiopoulou, Hung Nguyen, Evan Parker, Jukka Pekola, Martin Prest, Mika Prunnila, Juan Sebastian Reparaz, Andrey Shchepetov, Clivia Sotomayor-Torres, Katerina Valalaki, Terry Whall

Producción científica: Capítulo de libro › Capítulo › Investigación › revisión exhaustiva

Resumen

© ISTE Ltd 2014. All rights reserved. This chapter discusses the cooling of a platform, which requires the electronic coolers to extract heat by coupling to phonons within the platform material. Major results obtained within the nanofunction NoE on the development of nanomodulated magnetic materials and the investigation of their main properties are also presented. The cooling power of the devices becomes paramount, as opposed to the base temperature that could be reached, and must exceed heat leaks into the platform from the surroundings. This indirect cooling is desirable for systems where electrical isolation from the refrigeration elements is required, such as in quantum information applications or superconducting transition edge sensors (TESs). Thick porous Si layers on the Si wafer constitute alternative structures that could replace the rather fragile silicon nitride membranes for use as thermal isolation platforms. The structure and morphology of porous Si determines its electrical and thermal conductivity.

Idioma original	Inglés
Título de la publicación alojada	Beyond CMOS Nanodevices 1
Páginas	331-363
Número de páginas	32
Volumen	9781848216549
DOI	https://doi.org/10.1002/9781118984772.ch12
Estado	Publicada - 23 jun 2014

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Leadley, D., Shah, V., Ahopelto, J., Alzina, F., Chávez-Ángel, E., Muhonen, J., Myronov, M., Nassiopoulou, A. G., Nguyen, H., Parker, E., Pekola, J., Prest, M., Prunnila, M., Reparaz, J. S., Shchepetov, A., Sotomayor-Torres, C., Valalaki, K., & Whall, T. (2014). Thermal Isolation Through Nanostructuring. En Beyond CMOS Nanodevices 1 (Vol. 9781848216549, pp. 331-363) https://doi.org/10.1002/9781118984772.ch12

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abstract = "{\textcopyright} ISTE Ltd 2014. All rights reserved. This chapter discusses the cooling of a platform, which requires the electronic coolers to extract heat by coupling to phonons within the platform material. Major results obtained within the nanofunction NoE on the development of nanomodulated magnetic materials and the investigation of their main properties are also presented. The cooling power of the devices becomes paramount, as opposed to the base temperature that could be reached, and must exceed heat leaks into the platform from the surroundings. This indirect cooling is desirable for systems where electrical isolation from the refrigeration elements is required, such as in quantum information applications or superconducting transition edge sensors (TESs). Thick porous Si layers on the Si wafer constitute alternative structures that could replace the rather fragile silicon nitride membranes for use as thermal isolation platforms. The structure and morphology of porous Si determines its electrical and thermal conductivity.",

keywords = "Crystalline materials, Electronic coolers, Nanostructured porous Si layers, Nanostructuring, Thermal conductivity, Thermal isolation",

author = "David Leadley and Vishal Shah and Jouni Ahopelto and Francesc Alzina and Emigdio Ch{\'a}vez-{\'A}ngel and Juha Muhonen and Maksym Myronov and Nassiopoulou, \{Androula G.\} and Hung Nguyen and Evan Parker and Jukka Pekola and Martin Prest and Mika Prunnila and Reparaz, \{Juan Sebastian\} and Andrey Shchepetov and Clivia Sotomayor-Torres and Katerina Valalaki and Terry Whall",

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Leadley, D, Shah, V, Ahopelto, J, Alzina, F, Chávez-Ángel, E, Muhonen, J, Myronov, M, Nassiopoulou, AG, Nguyen, H, Parker, E, Pekola, J, Prest, M, Prunnila, M, Reparaz, JS, Shchepetov, A, Sotomayor-Torres, C, Valalaki, K & Whall, T 2014, Thermal Isolation Through Nanostructuring. En Beyond CMOS Nanodevices 1. vol. 9781848216549, pp. 331-363. https://doi.org/10.1002/9781118984772.ch12

TY - CHAP

T1 - Thermal Isolation Through Nanostructuring

AU - Leadley, David

AU - Shah, Vishal

AU - Ahopelto, Jouni

AU - Alzina, Francesc

AU - Chávez-Ángel, Emigdio

AU - Muhonen, Juha

AU - Myronov, Maksym

AU - Nassiopoulou, Androula G.

AU - Nguyen, Hung

AU - Parker, Evan

AU - Pekola, Jukka

AU - Prest, Martin

AU - Prunnila, Mika

AU - Reparaz, Juan Sebastian

AU - Shchepetov, Andrey

AU - Sotomayor-Torres, Clivia

AU - Valalaki, Katerina

AU - Whall, Terry

PY - 2014/6/23

Y1 - 2014/6/23

N2 - © ISTE Ltd 2014. All rights reserved. This chapter discusses the cooling of a platform, which requires the electronic coolers to extract heat by coupling to phonons within the platform material. Major results obtained within the nanofunction NoE on the development of nanomodulated magnetic materials and the investigation of their main properties are also presented. The cooling power of the devices becomes paramount, as opposed to the base temperature that could be reached, and must exceed heat leaks into the platform from the surroundings. This indirect cooling is desirable for systems where electrical isolation from the refrigeration elements is required, such as in quantum information applications or superconducting transition edge sensors (TESs). Thick porous Si layers on the Si wafer constitute alternative structures that could replace the rather fragile silicon nitride membranes for use as thermal isolation platforms. The structure and morphology of porous Si determines its electrical and thermal conductivity.

AB - © ISTE Ltd 2014. All rights reserved. This chapter discusses the cooling of a platform, which requires the electronic coolers to extract heat by coupling to phonons within the platform material. Major results obtained within the nanofunction NoE on the development of nanomodulated magnetic materials and the investigation of their main properties are also presented. The cooling power of the devices becomes paramount, as opposed to the base temperature that could be reached, and must exceed heat leaks into the platform from the surroundings. This indirect cooling is desirable for systems where electrical isolation from the refrigeration elements is required, such as in quantum information applications or superconducting transition edge sensors (TESs). Thick porous Si layers on the Si wafer constitute alternative structures that could replace the rather fragile silicon nitride membranes for use as thermal isolation platforms. The structure and morphology of porous Si determines its electrical and thermal conductivity.

KW - Crystalline materials

KW - Electronic coolers

KW - Nanostructured porous Si layers

KW - Nanostructuring

KW - Thermal conductivity

KW - Thermal isolation

UR - https://www.scopus.com/pages/publications/84926399291

U2 - 10.1002/9781118984772.ch12

DO - 10.1002/9781118984772.ch12

M3 - Chapter

SN - 9781118984772

SN - 9781848216549

VL - 9781848216549

SP - 331

EP - 363

BT - Beyond CMOS Nanodevices 1

ER -

Thermal Isolation Through Nanostructuring

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