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Giant Isotope Effect of Thermal Conductivity in Silicon Nanowires

Penghong Ci, Muhua Sun, Meenakshi Upadhyaya, Houfu Song, Lei Jin, Bo Sun, Matthew R. Jones, Joel W. Ager, Zlatan Akšamija, Junqiao Wu

2022Physical Review Letters27 citationsDOIOpen Access PDF

Abstract

Isotopically purified semiconductors potentially dissipate heat better than their natural, isotopically mixed counterparts as they have higher thermal conductivity (κ). But the benefit is low for Si at room temperature, amounting to only ∼10% higher κ for bulk ^{28}Si than for bulk natural Si (^{nat}Si). We show that in stark contrast to this bulk behavior, ^{28}Si (99.92% enriched) nanowires have up to 150% higher κ than ^{nat}Si nanowires with similar diameters and surface morphology. Using a first-principles phonon dispersion model, this giant isotope effect is attributed to a mutual enhancement of isotope scattering and surface scattering of phonons in ^{nat}Si nanowires, correlated via transmission of phonons to the native amorphous SiO_{2} shell. The Letter discovers the strongest isotope effect of κ at room temperature among all materials reported to date and inspires potential applications of isotopically enriched semiconductors in microelectronics.

Topics & Concepts

NanowireMicroelectronicsThermal conductivityMaterials sciencePhononSiliconScatteringSemiconductorCondensed matter physicsIsotopeKinetic isotope effectChemical physicsNanotechnologyOptoelectronicsAtomic physicsChemistryOpticsComposite materialPhysicsNuclear physicsDeuteriumThermal properties of materialsGraphene research and applicationsAdvanced Thermoelectric Materials and Devices
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