Ga2O3-on-SiC Composite Wafer for Thermal Management of Ultrawide Bandgap Electronics

Yiwen Song; Daniel Shoemaker; Jacob H. Leach; Craig McGray; Hsien Lien Huang; Arkka Bhattacharyya; Yingying Zhang; C. Ulises Gonzalez-Valle; Tina Hess; Sarit Zhukovsky; Kevin Ferri; Robert M. Lavelle; Carlos Perez; David W. Snyder; Jon Paul Maria; Bladimir Ramos-Alvarado; Xiaojia Wang; Sriram Krishnamoorthy; Jinwoo Hwang; Brian M. Foley; Sukwon Choi

doi:10.1021/acsami.1c09736

Ga₂O₃-on-SiC Composite Wafer for Thermal Management of Ultrawide Bandgap Electronics

Yiwen Song, Daniel Shoemaker, Jacob H. Leach, Craig McGray, Hsien Lien Huang, Arkka Bhattacharyya, Yingying Zhang, C. Ulises Gonzalez-Valle, Tina Hess, Sarit Zhukovsky, Kevin Ferri, Robert M. Lavelle, Carlos Perez, David W. Snyder, Jon Paul Maria, Bladimir Ramos-Alvarado, Xiaojia Wang, Sriram Krishnamoorthy, Jinwoo Hwang, Brian M. FoleySukwon Choi

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

53 Scopus citations

Abstract

β-phase gallium oxide (Ga2O3) is an emerging ultrawide bandgap (UWBG) semiconductor (EG ∼4.8 eV), which promises generational improvements in the performance and manufacturing cost over today's commercial wide bandgap power electronics based on GaN and SiC. However, overheating has been identified as a major bottleneck to the performance and commercialization of Ga2O3 device technologies. In this work, a novel Ga2O3/4H-SiC composite wafer with high heat transfer performance and an epi-ready surface finish has been developed using a fusion-bonding method. By taking advantage of low-temperature metalorganic vapor phase epitaxy, a Ga2O3 epitaxial layer was successfully grown on the composite wafer while maintaining the structural integrity of the composite wafer without causing interface damage. An atomically smooth homoepitaxial film with a room-temperature Hall mobility of ∼94 cm2/Vs and a volume charge of ∼3 × 1017 cm-3 was achieved at a growth temperature of 600 °C. Phonon transport across the Ga2O3/4H-SiC interface has been studied using frequency-domain thermoreflectance and a differential steady-state thermoreflectance approach. Scanning transmission electron microscopy analysis suggests that phonon transport across the Ga2O3/4H-SiC interface is dominated by the thickness of the SiNx bonding layer and an unintentionally formed SiOx interlayer. Extrinsic effects that impact the thermal conductivity of the 6.5 μm thick Ga2O3 layer were studied via time-domain thermoreflectance. Thermal simulation was performed to estimate the improvement of the thermal performance of a hypothetical single-finger Ga2O3 metal-semiconductor field-effect transistor fabricated on the composite substrate. This novel power transistor topology resulted in a ∼4.3× reduction in the junction-to-package device thermal resistance. Furthermore, an even more pronounced cooling effect is demonstrated when the composite wafer is implemented into the device design of practical multifinger devices. These innovations in device-level thermal management give promise to the full exploitation of the promising benefits of the UWBG material, which will lead to significant improvements in the power density and efficiency of power electronics over current state-of-the-art commercial devices.

Original language	English (US)
Pages (from-to)	40817-40829
Number of pages	13
Journal	ACS Applied Materials and Interfaces
Volume	13
Issue number	34
DOIs	https://doi.org/10.1021/acsami.1c09736
State	Published - Sep 1 2021

Bibliographical note

Publisher Copyright:
© 2021 American Chemical Society.

Keywords

composite substrate
fusion bonding
gallium oxide (GaO)
low-temperature metal organic vapor phase epitaxy (MOVPE)
thermal boundary resistance (TBR)
thermal management
ultrawide bandgap (UWBG) semiconductor devices

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access

10.1021/acsami.1c09736

OpenUrl availability

Full text

Cite this

Song, Y., Shoemaker, D., Leach, J. H., McGray, C., Huang, H. L., Bhattacharyya, A., Zhang, Y., Gonzalez-Valle, C. U., Hess, T., Zhukovsky, S., Ferri, K., Lavelle, R. M., Perez, C., Snyder, D. W., Maria, J. P., Ramos-Alvarado, B., Wang, X., Krishnamoorthy, S., Hwang, J., ... Choi, S. (2021). Ga₂O₃-on-SiC Composite Wafer for Thermal Management of Ultrawide Bandgap Electronics. ACS Applied Materials and Interfaces, 13(34), 40817-40829. https://doi.org/10.1021/acsami.1c09736

Song, Y, Shoemaker, D, Leach, JH, McGray, C, Huang, HL, Bhattacharyya, A, Zhang, Y, Gonzalez-Valle, CU, Hess, T, Zhukovsky, S, Ferri, K, Lavelle, RM, Perez, C, Snyder, DW, Maria, JP, Ramos-Alvarado, B, Wang, X, Krishnamoorthy, S, Hwang, J, Foley, BM & Choi, S 2021, 'Ga₂O₃-on-SiC Composite Wafer for Thermal Management of Ultrawide Bandgap Electronics', ACS Applied Materials and Interfaces, vol. 13, no. 34, pp. 40817-40829. https://doi.org/10.1021/acsami.1c09736

@article{af91b43b4c43487a95603a4859f28d10,

title = "Ga2O3-on-SiC Composite Wafer for Thermal Management of Ultrawide Bandgap Electronics",

abstract = "β-phase gallium oxide (Ga2O3) is an emerging ultrawide bandgap (UWBG) semiconductor (EG ∼4.8 eV), which promises generational improvements in the performance and manufacturing cost over today's commercial wide bandgap power electronics based on GaN and SiC. However, overheating has been identified as a major bottleneck to the performance and commercialization of Ga2O3 device technologies. In this work, a novel Ga2O3/4H-SiC composite wafer with high heat transfer performance and an epi-ready surface finish has been developed using a fusion-bonding method. By taking advantage of low-temperature metalorganic vapor phase epitaxy, a Ga2O3 epitaxial layer was successfully grown on the composite wafer while maintaining the structural integrity of the composite wafer without causing interface damage. An atomically smooth homoepitaxial film with a room-temperature Hall mobility of ∼94 cm2/Vs and a volume charge of ∼3 × 1017 cm-3 was achieved at a growth temperature of 600 °C. Phonon transport across the Ga2O3/4H-SiC interface has been studied using frequency-domain thermoreflectance and a differential steady-state thermoreflectance approach. Scanning transmission electron microscopy analysis suggests that phonon transport across the Ga2O3/4H-SiC interface is dominated by the thickness of the SiNx bonding layer and an unintentionally formed SiOx interlayer. Extrinsic effects that impact the thermal conductivity of the 6.5 μm thick Ga2O3 layer were studied via time-domain thermoreflectance. Thermal simulation was performed to estimate the improvement of the thermal performance of a hypothetical single-finger Ga2O3 metal-semiconductor field-effect transistor fabricated on the composite substrate. This novel power transistor topology resulted in a ∼4.3× reduction in the junction-to-package device thermal resistance. Furthermore, an even more pronounced cooling effect is demonstrated when the composite wafer is implemented into the device design of practical multifinger devices. These innovations in device-level thermal management give promise to the full exploitation of the promising benefits of the UWBG material, which will lead to significant improvements in the power density and efficiency of power electronics over current state-of-the-art commercial devices.",

keywords = "composite substrate, fusion bonding, gallium oxide (GaO), low-temperature metal organic vapor phase epitaxy (MOVPE), thermal boundary resistance (TBR), thermal management, ultrawide bandgap (UWBG) semiconductor devices",

author = "Yiwen Song and Daniel Shoemaker and Leach, {Jacob H.} and Craig McGray and Huang, {Hsien Lien} and Arkka Bhattacharyya and Yingying Zhang and Gonzalez-Valle, {C. Ulises} and Tina Hess and Sarit Zhukovsky and Kevin Ferri and Lavelle, {Robert M.} and Carlos Perez and Snyder, {David W.} and Maria, {Jon Paul} and Bladimir Ramos-Alvarado and Xiaojia Wang and Sriram Krishnamoorthy and Jinwoo Hwang and Foley, {Brian M.} and Sukwon Choi",

note = "Publisher Copyright: {\textcopyright} 2021 American Chemical Society.",

year = "2021",

month = sep,

day = "1",

doi = "10.1021/acsami.1c09736",

language = "English (US)",

volume = "13",

pages = "40817--40829",

journal = "ACS Applied Materials and Interfaces",

issn = "1944-8244",

publisher = "American Chemical Society",

number = "34",

}

TY - JOUR

T1 - Ga2O3-on-SiC Composite Wafer for Thermal Management of Ultrawide Bandgap Electronics

AU - Song, Yiwen

AU - Shoemaker, Daniel

AU - Leach, Jacob H.

AU - McGray, Craig

AU - Huang, Hsien Lien

AU - Bhattacharyya, Arkka

AU - Zhang, Yingying

AU - Gonzalez-Valle, C. Ulises

AU - Hess, Tina

AU - Zhukovsky, Sarit

AU - Ferri, Kevin

AU - Lavelle, Robert M.

AU - Perez, Carlos

AU - Snyder, David W.

AU - Maria, Jon Paul

AU - Ramos-Alvarado, Bladimir

AU - Wang, Xiaojia

AU - Krishnamoorthy, Sriram

AU - Hwang, Jinwoo

AU - Foley, Brian M.

AU - Choi, Sukwon

PY - 2021/9/1

Y1 - 2021/9/1

N2 - β-phase gallium oxide (Ga2O3) is an emerging ultrawide bandgap (UWBG) semiconductor (EG ∼4.8 eV), which promises generational improvements in the performance and manufacturing cost over today's commercial wide bandgap power electronics based on GaN and SiC. However, overheating has been identified as a major bottleneck to the performance and commercialization of Ga2O3 device technologies. In this work, a novel Ga2O3/4H-SiC composite wafer with high heat transfer performance and an epi-ready surface finish has been developed using a fusion-bonding method. By taking advantage of low-temperature metalorganic vapor phase epitaxy, a Ga2O3 epitaxial layer was successfully grown on the composite wafer while maintaining the structural integrity of the composite wafer without causing interface damage. An atomically smooth homoepitaxial film with a room-temperature Hall mobility of ∼94 cm2/Vs and a volume charge of ∼3 × 1017 cm-3 was achieved at a growth temperature of 600 °C. Phonon transport across the Ga2O3/4H-SiC interface has been studied using frequency-domain thermoreflectance and a differential steady-state thermoreflectance approach. Scanning transmission electron microscopy analysis suggests that phonon transport across the Ga2O3/4H-SiC interface is dominated by the thickness of the SiNx bonding layer and an unintentionally formed SiOx interlayer. Extrinsic effects that impact the thermal conductivity of the 6.5 μm thick Ga2O3 layer were studied via time-domain thermoreflectance. Thermal simulation was performed to estimate the improvement of the thermal performance of a hypothetical single-finger Ga2O3 metal-semiconductor field-effect transistor fabricated on the composite substrate. This novel power transistor topology resulted in a ∼4.3× reduction in the junction-to-package device thermal resistance. Furthermore, an even more pronounced cooling effect is demonstrated when the composite wafer is implemented into the device design of practical multifinger devices. These innovations in device-level thermal management give promise to the full exploitation of the promising benefits of the UWBG material, which will lead to significant improvements in the power density and efficiency of power electronics over current state-of-the-art commercial devices.

AB - β-phase gallium oxide (Ga2O3) is an emerging ultrawide bandgap (UWBG) semiconductor (EG ∼4.8 eV), which promises generational improvements in the performance and manufacturing cost over today's commercial wide bandgap power electronics based on GaN and SiC. However, overheating has been identified as a major bottleneck to the performance and commercialization of Ga2O3 device technologies. In this work, a novel Ga2O3/4H-SiC composite wafer with high heat transfer performance and an epi-ready surface finish has been developed using a fusion-bonding method. By taking advantage of low-temperature metalorganic vapor phase epitaxy, a Ga2O3 epitaxial layer was successfully grown on the composite wafer while maintaining the structural integrity of the composite wafer without causing interface damage. An atomically smooth homoepitaxial film with a room-temperature Hall mobility of ∼94 cm2/Vs and a volume charge of ∼3 × 1017 cm-3 was achieved at a growth temperature of 600 °C. Phonon transport across the Ga2O3/4H-SiC interface has been studied using frequency-domain thermoreflectance and a differential steady-state thermoreflectance approach. Scanning transmission electron microscopy analysis suggests that phonon transport across the Ga2O3/4H-SiC interface is dominated by the thickness of the SiNx bonding layer and an unintentionally formed SiOx interlayer. Extrinsic effects that impact the thermal conductivity of the 6.5 μm thick Ga2O3 layer were studied via time-domain thermoreflectance. Thermal simulation was performed to estimate the improvement of the thermal performance of a hypothetical single-finger Ga2O3 metal-semiconductor field-effect transistor fabricated on the composite substrate. This novel power transistor topology resulted in a ∼4.3× reduction in the junction-to-package device thermal resistance. Furthermore, an even more pronounced cooling effect is demonstrated when the composite wafer is implemented into the device design of practical multifinger devices. These innovations in device-level thermal management give promise to the full exploitation of the promising benefits of the UWBG material, which will lead to significant improvements in the power density and efficiency of power electronics over current state-of-the-art commercial devices.

KW - composite substrate

KW - fusion bonding

KW - gallium oxide (GaO)

KW - low-temperature metal organic vapor phase epitaxy (MOVPE)

KW - thermal boundary resistance (TBR)

KW - thermal management

KW - ultrawide bandgap (UWBG) semiconductor devices

UR - http://www.scopus.com/inward/record.url?scp=85114084129&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85114084129&partnerID=8YFLogxK

U2 - 10.1021/acsami.1c09736

DO - 10.1021/acsami.1c09736

M3 - Article

C2 - 34470105

AN - SCOPUS:85114084129

SN - 1944-8244

VL - 13

SP - 40817

EP - 40829

JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 34

ER -