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Coupling of near-field thermal radiative heating and phonon Monte Carlo simulation: Assessment of temperature gradient in n-doped silicon thin film

عنوان	Coupling of near-field thermal radiative heating and phonon Monte Carlo simulation: Assessment of temperature gradient in n-doped silicon thin film
نویسنده	Wong, B. T., Francoeur, M., Bong, V. N.-S., Mengüç, Mustafa Pınar
تاریخ انتشار:	2014-08
محل انتشار	- Elsevier
موضوع	Near-field thermal radiation, Near-field radiative heating, Monte Carlo phonon transport, Thermal gradient in thin film, Near-field radiation and phonon transport coupling
نوع	دوره ای
زبان	انگلیسی
دیجیتال	بله
نسخه خطی	خیر
کتابخانه:	دانشگاه اوزیغین
شناسه دارایی کتابخانه	0022-4073
شماره ثبت	074610e6-d0bc-419c-974e-5f0377a228c3
محل کتابخانه	Mechanical Engineering
تاریخ	2014-08
یادداشت‌ها	Due to copyright restrictions, the access to the full text of this article is only available via subscription.
متن نمونه	Near-field thermal radiative exchange between two objects is typically more effective than the far-field thermal radiative exchange as the heat flux can increase up to several orders higher in magnitudes due to tunneling of evanescent waves. Such an interesting phenomenon has started to gain its popularity in nanotechnology, especially in nano-gap thermophotovoltaic systems and near-field radiative cooling of micro-/nano-devices. Here, we explored the existence of thermal gradient within an n-doped silicon thin film when it is subjected to intensive near-field thermal radiative heating. The near-field radiative power density deposited within the film is calculated using the Maxwell equations combined with fluctuational electrodynamics. A phonon Monte Carlo simulation is then used to assess the temperature gradient by treating the near-field radiative power density as the heat source. Results indicated that it is improbable to have temperature gradient with the near-field radiative heating as a continuous source unless the source comprises of ultra-short radiative pulses with a strong power density.
DOI	10.1016/j.jqsrt.2013.09.002
Cilt	143

مشاهده در منبع دانشگاه اوزیغین Özyeğin Üniversitesi

دانشگاه اوزیغین

Coupling of near-field thermal radiative heating and phonon Monte Carlo simulation: Assessment of temperature gradient in n-doped silicon thin film

نویسنده Wong, B. T., Francoeur, M., Bong, V. N.-S., Mengüç, Mustafa Pınar

تاریخ انتشار 2014-08

محل انتشار - Elsevier

موضوع Near-field thermal radiation, Near-field radiative heating, Monte Carlo phonon transport, Thermal gradient in thin film, Near-field radiation and phonon transport coupling

نوع دوره ای

زبان انگلیسی

دیجیتال بله

نسخه خطی خیر

کتابخانه دانشگاه اوزیغین

شناسه دارایی کتابخانه 0022-4073

شماره ثبت 074610e6-d0bc-419c-974e-5f0377a228c3

محل کتابخانه Mechanical Engineering

تاریخ 2014-08

یادداشت‌ها Due to copyright restrictions, the access to the full text of this article is only available via subscription.

متن نمونه Near-field thermal radiative exchange between two objects is typically more effective than the far-field thermal radiative exchange as the heat flux can increase up to several orders higher in magnitudes due to tunneling of evanescent waves. Such an interesting phenomenon has started to gain its popularity in nanotechnology, especially in nano-gap thermophotovoltaic systems and near-field radiative cooling of micro-/nano-devices. Here, we explored the existence of thermal gradient within an n-doped silicon thin film when it is subjected to intensive near-field thermal radiative heating. The near-field radiative power density deposited within the film is calculated using the Maxwell equations combined with fluctuational electrodynamics. A phonon Monte Carlo simulation is then used to assess the temperature gradient by treating the near-field radiative power density as the heat source. Results indicated that it is improbable to have temperature gradient with the near-field radiative heating as a continuous source unless the source comprises of ultra-short radiative pulses with a strong power density.

DOI 10.1016/j.jqsrt.2013.09.002

Cilt 143