High thermal conductivity and ultrahigh thermal boundary conductance of homoepitaxial AlN thin films

Alvarez-Escalante, Gustavo; Page, Ryan; Hu, Renjiu; Xing, Huili Grace; Jena, Debdeep; Tian, Zhiting

doi:10.1063/5.0078155

Cited by 20 publications

(10 citation statements)

References 36 publications

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“…Further obscuring these relationships is the interplay of throw distance and ion mean free path, which itself is dependent upon a combination of pressure, applied power, and magnetic configuration of the 18,19,29,34,36−42 In (b), diamond symbols are single-crystal samples: Slack 43 (black), Rounds 44 (red), and Xu 16 (blue). Square symbols are for polycrystalline films: Kuo 19 (orange), Jacquot 45 (light blue), Zhao 36 (purple), Choi 37 (red), Pan 39 (cyan), Aissa 40 (pink), Duquenne 38 (green), Alvarez-Escalante (light green), 42 Bian 41 (dark green), Yalon 29 (black), Cheng 18 (yellow), Koh 20 (brown), and Bellerk 46 (magenta). Round symbols correspond to amorphous thin films: Zhao 36 (purple) and Gaskins 34 (black).…”

Section: Resultsmentioning

confidence: 99%

High Thermal Conductivity of Submicrometer Aluminum Nitride Thin Films Sputter-Deposited at Low Temperature

Perez,

McLeod,

Chen

et al. 2023

ACS Nano

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Aluminum nitride (AlN) is one of the few electrically insulating materials with excellent thermal conductivity, but high-quality films typically require exceedingly hot deposition temperatures (>1000 °C). For thermal management applications in dense or high-power integrated circuits, it is important to deposit heat spreaders at low temperatures (<500 °C), without affecting the underlying electronics. Here, we demonstrate 100 nm to 1.7 μm thick AlN films achieved by lowtemperature (<100 °C) sputtering, correlating their thermal properties with their grain size and interfacial quality, which we analyze by X-ray diffraction, transmission X-ray microscopy, as well as Raman and Auger spectroscopy. Controlling the deposition conditions through the partial pressure of reactive N 2 , we achieve an ∼3× variation in thermal conductivity (∼36−104 W m −1 K −1 ) of ∼600 nm films, with the upper range representing one of the highest values for such film thicknesses at room temperature, especially at deposition temperatures below 100 °C. Defect densities are also estimated from the thermal conductivity measurements, providing insight into the thermal engineering of AlN that can be optimized for application-specific heat spreading or thermal confinement.

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Section: Resultsmentioning

confidence: 99%

High Thermal Conductivity of Submicrometer Aluminum Nitride Thin Films Sputter-Deposited at Low Temperature

Perez,

McLeod,

Chen

et al. 2023

ACS Nano

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“…For better thermal management, high-thermal-conductivity materials such as SiC and diamond can be used as the substrate. More recently, the growth of AlN has reached a maturity, making it another promising substrate candidate. − …”

Section: Introductionmentioning

confidence: 99%

A Critical Review of Thermal Boundary Conductance across Wide and Ultrawide Bandgap Semiconductor Interfaces

Feng

Zhou

Cheng

et al. 2023

ACS Appl. Mater. Interfaces

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The emergence of wide and ultrawide bandgap semiconductors has revolutionized the advancement of next-generation power, radio frequency, and opto- electronics, paving the way for chargers, renewable energy inverters, 5G base stations, satellite communications, radars, and light-emitting diodes. However, the thermal boundary resistance at semiconductor interfaces accounts for a large portion of the near-junction thermal resistance, impeding heat dissipation and becoming a bottleneck in the devices’ development. Over the past two decades, many new ultrahigh thermal conductivity materials have emerged as potential substrates, and numerous novel growth, integration, and characterization techniques have emerged to improve the TBC, holding great promise for efficient cooling. At the same time, numerous simulation methods have been developed to advance the understanding and prediction of TBC. Despite these advancements, the existing literature reports are widely dispersed, presenting varying TBC results even on the same heterostructure, and there is a large gap between experiments and simulations. Herein, we comprehensively review the various experimental and simulation works that reported TBCs of wide and ultrawide bandgap semiconductor heterostructures, aiming to build a structure–property relationship between TBCs and interfacial nanostructures and to further boost the TBCs. The advantages and disadvantages of various experimental and theoretical methods are summarized. Future directions for experimental and theoretical research are proposed.

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“…Cross-Plane Thermal Conductivity: The cross-plane thermal conductivity k ⊥ was measured using the optical pump-probe method of FDTR. [64,65] An FDTR system was implemented with two continuous-wave lasers: a 488 nm pump and a 532 nm probe (Figure S8, Supporting Information). The vertically polarized pump beam first travels through an optical isolator.…”

Section: Methodsmentioning

confidence: 99%

Non‐Linear Optics at Twist Interfaces in h‐BN/SiC Heterostructures

Biswas,

Xu,

Alvarez

et al. 2023

Advanced Materials

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Understanding the emergent electronic structure in twisted atomically thin layers has led to the exciting field of twistronics. However, practical applications of such systems are challenging since the specific angular correlations between the layers must be precisely controlled and the layers have to be single crystalline with uniform atomic ordering. Here, we suggest an alternative, simple and scalable approach where nanocrystalline two‐dimensional (2D) film on three‐dimensional (3D) substrates yield twisted‐interface‐dependent properties. Ultrawide‐bandgap hexagonal boron nitride (h‐BN) thin films are directly grown on high in‐plane lattice mismatched wide‐bandgap silicon carbide (4H‐SiC) substrates to explore the twist‐dependent structure‐property correlations. Concurrently, nanocrystalline h‐BN thin film shows strong non‐linear second‐harmonic generation and ultra‐low cross‐plane thermal conductivity at room temperature, which are attributed to the twisted domain edges between van der Waals stacked nanocrystals with random in‐plane orientations. First‐principles calculations based on time‐dependent density functional theory manifest strong even‐order optical nonlinearity in twisted h‐BN layers. Our work unveils that directly deposited 2D nanocrystalline thin film on 3D substrates could provide easily accessible twist‐interfaces, therefore enabling a simple and scalable approach to utilize the 2D‐twistronics integrated in 3D material devices for next‐generation nanotechnology.This article is protected by copyright. All rights reserved

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High thermal conductivity and ultrahigh thermal boundary conductance of homoepitaxial AlN thin films

Cited by 20 publications

References 36 publications

High Thermal Conductivity of Submicrometer Aluminum Nitride Thin Films Sputter-Deposited at Low Temperature

High Thermal Conductivity of Submicrometer Aluminum Nitride Thin Films Sputter-Deposited at Low Temperature

A Critical Review of Thermal Boundary Conductance across Wide and Ultrawide Bandgap Semiconductor Interfaces

Non‐Linear Optics at Twist Interfaces in h‐BN/SiC Heterostructures

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