Jeffrey L. Braun scite author profile

Manipulating a crystalline material's configurational entropy through the introduction of unique atomic species can produce novel materials with desirable mechanical and electrical properties. From a thermal transport perspective, large differences between elemental properties such as mass and interatomic force can reduce the rate at which phonons carry heat and thus reduce the thermal conductivity. Recent advances in materials synthesis are enabling the fabrication of entropy-stabilized ceramics, opening the door for understanding the implications of extreme disorder on thermal transport. Measuring the structural, mechanical, and thermal properties of single-crystal entropy-stabilized oxides, it is shown that local ionic charge disorder can effectively reduce thermal conductivity without compromising mechanical stiffness. These materials demonstrate similar thermal conductivities to their amorphous counterparts, in agreement with the theoretical minimum limit, resulting in this class of material possessing the highest ratio of elastic modulus to thermal conductivity of any isotropic crystal. CeramicsHigh-entropy alloys (HEAs), consisting of five or more approximately equimolar compositions of elements, [1,2] have proven to exhibit unique physical properties such as high hardness, [3] thermal stability, [4] structural stability, [5] as well as corrosion, oxidation, and wear resistance. [6][7][8] While microstructure and mechanical properties have been extensively studied, thermal

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Size effects on the thermal conductivity of amorphous silicon thin films

Braun

et al. 2016

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We investigate thickness-limited size effects on the thermal conductivity of amorphous silicon thin films ranging from 3 -1636 nm grown via sputter deposition. While exhibiting a constant value up to ∼100 nm, the thermal conductivity increases with film thickness thereafter. This trend is in stark contrast with previous thermal conductivity measurements of amorphous systems, which have shown thickness-independent thermal conductivities. The thickness dependence we demonstrate is ascribed to boundary scattering of long wavelength vibrations and an interplay between the energy transfer associated with propagating modes (propagons) and nonpropagating modes (diffusons). A crossover from propagon to diffuson modes is deduced to occur at a frequency of ∼1.8 THz via simple analytical arguments. These results provide empirical evidence of size effects on the thermal conductivity of amorphous silicon and systematic experimental insight into the nature of vibrational thermal transport in amorphous solids.

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A high-entropy silicide: (Mo0.2Nb0.2Ta0.2Ti0.2W0.2)Si2

Gild

Braun

Kaufmann

et al. 2019

Journal of Materiomics

232

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Thermal conductivity and hardness of three single-phase high-entropy metal diborides fabricated by borocarbothermal reduction and spark plasma sintering

Gild

Wright

Quiambao-Tomko

et al. 2020

Ceramics International

138

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Jeffrey L. Braun

High-entropy fluorite oxides

Charge‐Induced Disorder Controls the Thermal Conductivity of Entropy‐Stabilized Oxides

Size effects on the thermal conductivity of amorphous silicon thin films

A high-entropy silicide: (Mo0.2Nb0.2Ta0.2Ti0.2W0.2)Si2

Thermal conductivity and hardness of three single-phase high-entropy metal diborides fabricated by borocarbothermal reduction and spark plasma sintering

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