Salvato in:
Dettagli Bibliografici
Autore principale: Jin, Jae Sik
Natura: Preprint
Pubblicazione: 2025
Soggetti:
Accesso online:https://arxiv.org/abs/2510.12530
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866911209885794304
author Jin, Jae Sik
author_facet Jin, Jae Sik
contents Phonon transport near nanoscale hotspots (NHs) critically determines heat dissipation in advanced electronic devices. The prevailing understanding is that the enhanced thermal resistance (TR) observed in NHs originates from long mean free path (MFP) phonons, whose MFPs are much larger than the hotspot size, thereby limiting their ability to recognize hotspots and transport heat effectively. In this study, we revisit this problem by employing the Boltzmann transport equation (BTE) with a full phonon dispersion model (FPDM) to capture mode-resolved velocities, scattering processes, and nonequilibrium phonon populations in silicon. The analysis demonstrates that the increase in TR near NHs is not caused by the long MFP itself but by the low specific heat of long-MFP phonons that do not scatter directly with optical modes. These phonons heat readily when energy is supplied, steepening the local temperature gradient near the NH and thereby enhancing TR. By resolving the spectral contributions to the phonon transport resistance and temperature gradients, we identify the critical role of the modal specific heat in nonlocal phonon transport. These results provide new physical insights into nanoscale thermal management and highlight the importance of spectral mode resolution in modeling heat dissipation in electronic devices.
format Preprint
id arxiv_https___arxiv_org_abs_2510_12530
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Origin of Enhanced Thermal Resistance Near Nanoscale Hotspots: Insights from Full-Dispersion-Resolved Phonon Transport in Silicon
Jin, Jae Sik
Mesoscale and Nanoscale Physics
Phonon transport near nanoscale hotspots (NHs) critically determines heat dissipation in advanced electronic devices. The prevailing understanding is that the enhanced thermal resistance (TR) observed in NHs originates from long mean free path (MFP) phonons, whose MFPs are much larger than the hotspot size, thereby limiting their ability to recognize hotspots and transport heat effectively. In this study, we revisit this problem by employing the Boltzmann transport equation (BTE) with a full phonon dispersion model (FPDM) to capture mode-resolved velocities, scattering processes, and nonequilibrium phonon populations in silicon. The analysis demonstrates that the increase in TR near NHs is not caused by the long MFP itself but by the low specific heat of long-MFP phonons that do not scatter directly with optical modes. These phonons heat readily when energy is supplied, steepening the local temperature gradient near the NH and thereby enhancing TR. By resolving the spectral contributions to the phonon transport resistance and temperature gradients, we identify the critical role of the modal specific heat in nonlocal phonon transport. These results provide new physical insights into nanoscale thermal management and highlight the importance of spectral mode resolution in modeling heat dissipation in electronic devices.
title Origin of Enhanced Thermal Resistance Near Nanoscale Hotspots: Insights from Full-Dispersion-Resolved Phonon Transport in Silicon
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2510.12530