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Autori principali: Shen, Yang, Song, Shangzhi, Chen, Tao, Zhang, Kexin, Chen, Yu, Zhao, Lu, Jiang, Puqing
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.07740
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author Shen, Yang
Song, Shangzhi
Chen, Tao
Zhang, Kexin
Chen, Yu
Zhao, Lu
Jiang, Puqing
author_facet Shen, Yang
Song, Shangzhi
Chen, Tao
Zhang, Kexin
Chen, Yu
Zhao, Lu
Jiang, Puqing
contents As integrated circuits continue to scale down and adopt three-dimensional (3D) stacking, thermal management in the back-end-of-line (BEOL) has emerged as a critical design constraint. In this study, we present a combined experimental and simulation framework to quantitatively characterize and mechanistically understand thermal transport in BEOL multilayers. Using the Square-Pulsed Source (SPS) method, a time-resolved optical metrology technique, we measure cross-plane thermal resistance and areal heat capacity in semiconductor chips at nanometer resolution. Two fabricated chip samples, polished to the M4 and M6 interconnection layers, are analyzed to extract thermal properties of distinct multilayer stacks. Results show that thermal resistance follows a series model, while areal heat capacity scales linearly with metal content. To uncover the underlying physical mechanisms, we perform finite element simulations using COMSOL Multiphysics, examining the influence of via connectivity and dielectric thermal conductivity on effective cross-plane heat transport. The simulations reveal that dielectric materials, due to their large volume fraction, are the primary limiting factor in BEOL thermal conduction, while the via structure plays a secondary but significant role. This combined experimental-simulation approach provides mechanistic insight into heat transport in advanced IC architectures and offers practical guidance for optimizing thermal pathways in future high-performance 3D-stacked devices.
format Preprint
id arxiv_https___arxiv_org_abs_2508_07740
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Mechanistic Insight into BEOL Thermal Transport via Optical Metrology and Multiphysics Simulation
Shen, Yang
Song, Shangzhi
Chen, Tao
Zhang, Kexin
Chen, Yu
Zhao, Lu
Jiang, Puqing
Mesoscale and Nanoscale Physics
As integrated circuits continue to scale down and adopt three-dimensional (3D) stacking, thermal management in the back-end-of-line (BEOL) has emerged as a critical design constraint. In this study, we present a combined experimental and simulation framework to quantitatively characterize and mechanistically understand thermal transport in BEOL multilayers. Using the Square-Pulsed Source (SPS) method, a time-resolved optical metrology technique, we measure cross-plane thermal resistance and areal heat capacity in semiconductor chips at nanometer resolution. Two fabricated chip samples, polished to the M4 and M6 interconnection layers, are analyzed to extract thermal properties of distinct multilayer stacks. Results show that thermal resistance follows a series model, while areal heat capacity scales linearly with metal content. To uncover the underlying physical mechanisms, we perform finite element simulations using COMSOL Multiphysics, examining the influence of via connectivity and dielectric thermal conductivity on effective cross-plane heat transport. The simulations reveal that dielectric materials, due to their large volume fraction, are the primary limiting factor in BEOL thermal conduction, while the via structure plays a secondary but significant role. This combined experimental-simulation approach provides mechanistic insight into heat transport in advanced IC architectures and offers practical guidance for optimizing thermal pathways in future high-performance 3D-stacked devices.
title Mechanistic Insight into BEOL Thermal Transport via Optical Metrology and Multiphysics Simulation
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2508.07740