Probing electronic dead layers in homoepitaxial n -SrTiO3(001) films

S. A. Chambers; D. Lee; Z. Yang; Y. Huang; W. Samarakoon; H. Zhou; P. V. Sushko; T. K. Truttmann; L. W. Wangoh; T. L. Lee; J. Gabel; B. Jalan

doi:10.1063/5.0098500

Probing electronic dead layers in homoepitaxial n -SrTiO₃(001) films

S. A. Chambers
, D. Lee
, Z. Yang
, Y. Huang
, W. Samarakoon
, H. Zhou
, P. V. Sushko
, T. K. Truttmann
, L. W. Wangoh
, T. L. Lee
, J. Gabel
, B. Jalan

Pacific Northwest National Laboratory
University of Minnesota Twin Cities
Oregon State University
United States Department of Energy
IBM
Diamond Light Source

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

4 Scopus citations

Abstract

We combine state-of-the-art oxide epitaxial growth by hybrid molecular beam epitaxy with transport, x-ray photoemission, and surface diffraction, along with classical and first-principles quantum mechanical modeling to investigate the nuances of insulating layer formation in otherwise high-mobility homoepitaxial n-SrTiO3(001) films. Our analysis points to charge immobilization at the buried n-SrTiO3/undoped SrTiO3(001) interface as well as within the surface contamination layer resulting from air exposure as the drivers of electronic dead-layer formation. As Fermi level equilibration occurs at the surface and the buried interface, charge trapping reduces the sheet carrier density (n2D) and renders the n-STO film insulating if n2D falls below the critical value for the metal-to-insulator transition.

Original language	English
Article number	070903
Journal	APL Materials
Volume	10
Issue number	7
DOIs	https://doi.org/10.1063/5.0098500
State	Published - 1 Jul 2022

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10.1063/5.0098500

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title = "Probing electronic dead layers in homoepitaxial n -SrTiO3(001) films",

abstract = "We combine state-of-the-art oxide epitaxial growth by hybrid molecular beam epitaxy with transport, x-ray photoemission, and surface diffraction, along with classical and first-principles quantum mechanical modeling to investigate the nuances of insulating layer formation in otherwise high-mobility homoepitaxial n-SrTiO3(001) films. Our analysis points to charge immobilization at the buried n-SrTiO3/undoped SrTiO3(001) interface as well as within the surface contamination layer resulting from air exposure as the drivers of electronic dead-layer formation. As Fermi level equilibration occurs at the surface and the buried interface, charge trapping reduces the sheet carrier density (n2D) and renders the n-STO film insulating if n2D falls below the critical value for the metal-to-insulator transition.",

author = "Chambers, \{S. A.\} and D. Lee and Z. Yang and Y. Huang and W. Samarakoon and H. Zhou and Sushko, \{P. V.\} and Truttmann, \{T. K.\} and Wangoh, \{L. W.\} and Lee, \{T. L.\} and J. Gabel and B. Jalan",

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doi = "10.1063/5.0098500",

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T1 - Probing electronic dead layers in homoepitaxial n -SrTiO3(001) films

AU - Chambers, S. A.

AU - Lee, D.

AU - Yang, Z.

AU - Huang, Y.

AU - Samarakoon, W.

AU - Zhou, H.

AU - Sushko, P. V.

AU - Truttmann, T. K.

AU - Wangoh, L. W.

AU - Lee, T. L.

AU - Gabel, J.

AU - Jalan, B.

PY - 2022/7/1

Y1 - 2022/7/1

N2 - We combine state-of-the-art oxide epitaxial growth by hybrid molecular beam epitaxy with transport, x-ray photoemission, and surface diffraction, along with classical and first-principles quantum mechanical modeling to investigate the nuances of insulating layer formation in otherwise high-mobility homoepitaxial n-SrTiO3(001) films. Our analysis points to charge immobilization at the buried n-SrTiO3/undoped SrTiO3(001) interface as well as within the surface contamination layer resulting from air exposure as the drivers of electronic dead-layer formation. As Fermi level equilibration occurs at the surface and the buried interface, charge trapping reduces the sheet carrier density (n2D) and renders the n-STO film insulating if n2D falls below the critical value for the metal-to-insulator transition.

AB - We combine state-of-the-art oxide epitaxial growth by hybrid molecular beam epitaxy with transport, x-ray photoemission, and surface diffraction, along with classical and first-principles quantum mechanical modeling to investigate the nuances of insulating layer formation in otherwise high-mobility homoepitaxial n-SrTiO3(001) films. Our analysis points to charge immobilization at the buried n-SrTiO3/undoped SrTiO3(001) interface as well as within the surface contamination layer resulting from air exposure as the drivers of electronic dead-layer formation. As Fermi level equilibration occurs at the surface and the buried interface, charge trapping reduces the sheet carrier density (n2D) and renders the n-STO film insulating if n2D falls below the critical value for the metal-to-insulator transition.

UR - https://www.scopus.com/pages/publications/85134890703

U2 - 10.1063/5.0098500

DO - 10.1063/5.0098500

M3 - Article

AN - SCOPUS:85134890703

SN - 2166-532X

VL - 10

JO - APL Materials

JF - APL Materials

IS - 7

M1 - 070903

ER -

Probing electronic dead layers in homoepitaxial n -SrTiO₃(001) films

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