Time-dependent conduction mechanisms in reversed stepped superlattice layers of GaN HEMTs on 200 mm engineered substrates

Zequan Chen; Michael J Uren; Henry Huang; Indraneel Sanyal; Matthew D Smith; Anurag Vohra; Sujit Kumar; Stefaan Decoutere; Benoit Bakeroot; Martin H H Kuball

doi:10.1063/5.0222572

Time-dependent conduction mechanisms in reversed stepped superlattice layers of GaN HEMTs on 200 mm engineered substrates

Zequan Chen, Michael J Uren, Henry Huang, Indraneel Sanyal, Matthew D Smith, Anurag Vohra, Sujit Kumar, Stefaan Decoutere, Benoit Bakeroot, Martin H H Kuball^*

^*Corresponding author for this work

Research output: Contribution to journal › Letter (Academic Journal) › peer-review

1 Citation (Scopus)

Abstract

Time-dependent conduction in epitaxial superlattice (SL) strain relief layers of GaN high electron mobility transistors on 200 mm engineered substrates with a poly-AlN core was observed and analyzed. This phenomenon occurs when the devices were operated with substrate bias of ∼−300 V for 10¹–10³ s. The formation of the conduction path is related to trap-assisted leakage through the SLs on the engineered substrates; de-trapped carriers spread out vertically and laterally within a portion of the SLs, leading to a higher electrical field across the rest of the layers. This conduction mechanism may be hidden during the devices' normal operation (target 650–1200 V). It could lead to undesired effects during the operation of the devices, such as a time-dependent dynamic R_on. More resistive SLs will potentially reduce the impact of this phenomenon.

Original language	English
Article number	093505
Number of pages	5
Journal	Applied Physics Letters
Volume	125
Issue number	9
DOIs	https://doi.org/10.1063/5.0222572
Publication status	Published - 28 Aug 2024

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@article{b8603ebcb2ac413a8cdfcbb528ae6f39,

title = "Time-dependent conduction mechanisms in reversed stepped superlattice layers of GaN HEMTs on 200 mm engineered substrates",

abstract = "Time-dependent conduction in epitaxial superlattice (SL) strain relief layers of GaN high electron mobility transistors on 200 mm engineered substrates with a poly-AlN core was observed and analyzed. This phenomenon occurs when the devices were operated with substrate bias of ∼−300 V for 101–103 s. The formation of the conduction path is related to trap-assisted leakage through the SLs on the engineered substrates; de-trapped carriers spread out vertically and laterally within a portion of the SLs, leading to a higher electrical field across the rest of the layers. This conduction mechanism may be hidden during the devices' normal operation (target 650–1200 V). It could lead to undesired effects during the operation of the devices, such as a time-dependent dynamic Ron. More resistive SLs will potentially reduce the impact of this phenomenon.",

author = "Zequan Chen and Uren, {Michael J} and Henry Huang and Indraneel Sanyal and Smith, {Matthew D} and Anurag Vohra and Sujit Kumar and Stefaan Decoutere and Benoit Bakeroot and Kuball, {Martin H H}",

year = "2024",

month = aug,

day = "28",

doi = "10.1063/5.0222572",

language = "English",

volume = "125",

journal = "Applied Physics Letters",

issn = "0003-6951",

publisher = "American Institute of Physics (AIP)",

number = "9",

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TY - JOUR

T1 - Time-dependent conduction mechanisms in reversed stepped superlattice layers of GaN HEMTs on 200 mm engineered substrates

AU - Chen, Zequan

AU - Uren, Michael J

AU - Huang, Henry

AU - Sanyal, Indraneel

AU - Smith, Matthew D

AU - Vohra, Anurag

AU - Kumar, Sujit

AU - Decoutere, Stefaan

AU - Bakeroot, Benoit

AU - Kuball, Martin H H

PY - 2024/8/28

Y1 - 2024/8/28

N2 - Time-dependent conduction in epitaxial superlattice (SL) strain relief layers of GaN high electron mobility transistors on 200 mm engineered substrates with a poly-AlN core was observed and analyzed. This phenomenon occurs when the devices were operated with substrate bias of ∼−300 V for 101–103 s. The formation of the conduction path is related to trap-assisted leakage through the SLs on the engineered substrates; de-trapped carriers spread out vertically and laterally within a portion of the SLs, leading to a higher electrical field across the rest of the layers. This conduction mechanism may be hidden during the devices' normal operation (target 650–1200 V). It could lead to undesired effects during the operation of the devices, such as a time-dependent dynamic Ron. More resistive SLs will potentially reduce the impact of this phenomenon.

AB - Time-dependent conduction in epitaxial superlattice (SL) strain relief layers of GaN high electron mobility transistors on 200 mm engineered substrates with a poly-AlN core was observed and analyzed. This phenomenon occurs when the devices were operated with substrate bias of ∼−300 V for 101–103 s. The formation of the conduction path is related to trap-assisted leakage through the SLs on the engineered substrates; de-trapped carriers spread out vertically and laterally within a portion of the SLs, leading to a higher electrical field across the rest of the layers. This conduction mechanism may be hidden during the devices' normal operation (target 650–1200 V). It could lead to undesired effects during the operation of the devices, such as a time-dependent dynamic Ron. More resistive SLs will potentially reduce the impact of this phenomenon.

U2 - 10.1063/5.0222572

DO - 10.1063/5.0222572

M3 - Letter (Academic Journal)

SN - 0003-6951

VL - 125

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 9

M1 - 093505

ER -

Time-dependent conduction mechanisms in reversed stepped superlattice layers of GaN HEMTs on 200 mm engineered substrates

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