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Molecular self-assembled monolayers anomalously enhance thermal conductance across polymer–semiconductor interfaces

Jinlong He, Lei Tao, Weikang Xian, Tom Arbaugh, Ying Li

2022Nanoscale13 citationsDOI

Abstract

, -SH, and -Cl, are orderly assembled into Si-PS interfaces. Their roles in ITC and the heat transfer mechanism were systematically investigated. Molecular simulations demonstrate that the Si-PS interface decorated with SAM molecules can significantly facilitate heat transfer in varying degrees. Such a difference is primarily due to the different non-bonded interactions and compatibility between SAMs and PS. Compared with the pristine Si-PS interface, the interface incorporated with 3-chloropropyl trimethoxysilane shows the greatest improvement in ITC, about 507.02%. Such improvements are largely attributed to the SAM molecules, as the thermal bridges straighten the molecular SAM chains, develop strong non-bonded interactions with PS, provide the covalent bonding between Si and PS, exhibit a strong coupling effect between two materials' vibrational modes, and eliminate the discontinuities in the temperature field. Eventually, these demonstrations are expected to offer molecular insights to enable effective thermal management through surface engineering for critical-heat transfer materials and microelectronic devices.

Topics & Concepts

MonolayerMaterials scienceMicroelectronicsInterfacial thermal resistanceSelf-assembled monolayerPolymerSemiconductorSiliconNanotechnologyChemical physicsMoleculeThermal conductivityPolystyreneSilaneThermal resistanceThermalOptoelectronicsChemistryComposite materialOrganic chemistryThermodynamicsPhysicsThermal properties of materialsMolecular Junctions and NanostructuresAdvanced Thermoelectric Materials and Devices
Molecular self-assembled monolayers anomalously enhance thermal conductance across polymer–semiconductor interfaces | Litcius