TY - JOUR
T1 - Tunable Thermal Energy Transport across Diamond Membranes and Diamond-Si Interfaces by Nanoscale Graphoepitaxy
AU - Cheng, Zhe
AU - Bai, Tingyu
AU - Shi, Jingjing
AU - Feng, Tianli
AU - Wang, Yekan
AU - Mecklenburg, Matthew
AU - Li, Chao
AU - Hobart, Karl D.
AU - Feygelson, Tatyana I.
AU - Tadjer, Marko J.
AU - Pate, Bradford B.
AU - Foley, Brian M.
AU - Yates, Luke
AU - Pantelides, Sokrates T.
AU - Cola, Baratunde A.
AU - Goorsky, Mark
AU - Graham, Samuel
N1 - Publisher Copyright:
© 2019 American Chemical Society.
PY - 2019/5/22
Y1 - 2019/5/22
N2 - The development of electronic devices, especially those that involve heterogeneous integration of materials, has led to increased challenges in addressing their thermal operational temperature demands. The heat flow in these systems is significantly influenced or even dominated by thermal boundary resistance at the interface between dissimilar materials. However, controlling and tuning heat transport across an interface and in the adjacent materials has so far drawn limited attention. In this work, we grow chemical vapor-deposited diamond on silicon substrates by graphoepitaxy and experimentally demonstrate tunable thermal transport across diamond membranes and diamond-silicon interfaces. We observed the highest diamond-silicon thermal boundary conductance (TBC) measured to date and increased diamond thermal conductivity due to strong grain texturing in the diamond near the interface. Additionally, nonequilibrium molecular dynamics simulations and a Landauer approach are used to understand the diamond-silicon TBC. These findings pave the way for tuning or increasing thermal conductance in heterogeneously integrated electronics that involve polycrystalline materials and will impact applications including electronics thermal management and diamond growth.
AB - The development of electronic devices, especially those that involve heterogeneous integration of materials, has led to increased challenges in addressing their thermal operational temperature demands. The heat flow in these systems is significantly influenced or even dominated by thermal boundary resistance at the interface between dissimilar materials. However, controlling and tuning heat transport across an interface and in the adjacent materials has so far drawn limited attention. In this work, we grow chemical vapor-deposited diamond on silicon substrates by graphoepitaxy and experimentally demonstrate tunable thermal transport across diamond membranes and diamond-silicon interfaces. We observed the highest diamond-silicon thermal boundary conductance (TBC) measured to date and increased diamond thermal conductivity due to strong grain texturing in the diamond near the interface. Additionally, nonequilibrium molecular dynamics simulations and a Landauer approach are used to understand the diamond-silicon TBC. These findings pave the way for tuning or increasing thermal conductance in heterogeneously integrated electronics that involve polycrystalline materials and will impact applications including electronics thermal management and diamond growth.
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U2 - 10.1021/acsami.9b02234
DO - 10.1021/acsami.9b02234
M3 - Article
C2 - 31042348
AN - SCOPUS:85066137935
SN - 1944-8244
VL - 11
SP - 18517
EP - 18527
JO - ACS Applied Materials and Interfaces
JF - ACS Applied Materials and Interfaces
IS - 20
ER -