Saved in:
Bibliographic Details
Main Authors: Campbell, Quinn T., Lopez, Manny Xavier de Jesus, Rice, Anthony, Ruggles, Timothy J., Ohta, Taisuke, McCowan, Caitlin, Addamane, Sadhvikas, Schmucker, Scott W., Koepke, Justine
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.10968
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911506425184256
author Campbell, Quinn T.
Lopez, Manny Xavier de Jesus
Rice, Anthony
Ruggles, Timothy J.
Ohta, Taisuke
McCowan, Caitlin
Addamane, Sadhvikas
Schmucker, Scott W.
Koepke, Justine
author_facet Campbell, Quinn T.
Lopez, Manny Xavier de Jesus
Rice, Anthony
Ruggles, Timothy J.
Ohta, Taisuke
McCowan, Caitlin
Addamane, Sadhvikas
Schmucker, Scott W.
Koepke, Justine
contents Remote epitaxy, where a 2D van der Waals material (usually graphene) is inserted on top of the substrate before film epitaxy, has emerged as a promising path for growing electronics with lower defect rates and less stringent lattice matching requirements. The exact mechanism behind remote epitaxy has not been definitively shown, however, and it is not obvious when examining a new substrate-film pair whether they would be compatible with the remote epitaxy process. In this paper, we use first principles calculations to test several different mechanisms for determining whether a given substrate-film pair will successfully be grown with remote epitaxy. We find that previously calculated metrics such as electrostatic potential do not hold sufficient explanatory power. We find that the sliding barrier of small islands on the surface when the atomic positions are allowed to optimize provides the most rigorous criteria for whether a given substrate-film pair is remote epitaxy active. This indicates that remote epitaxy is likely a phenomenon related to the kinetics and ease of island migration on the graphene surface.
format Preprint
id arxiv_https___arxiv_org_abs_2603_10968
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Island Sliding Barriers: A first-principles metric for determining remote epitaxy viability
Campbell, Quinn T.
Lopez, Manny Xavier de Jesus
Rice, Anthony
Ruggles, Timothy J.
Ohta, Taisuke
McCowan, Caitlin
Addamane, Sadhvikas
Schmucker, Scott W.
Koepke, Justine
Materials Science
Remote epitaxy, where a 2D van der Waals material (usually graphene) is inserted on top of the substrate before film epitaxy, has emerged as a promising path for growing electronics with lower defect rates and less stringent lattice matching requirements. The exact mechanism behind remote epitaxy has not been definitively shown, however, and it is not obvious when examining a new substrate-film pair whether they would be compatible with the remote epitaxy process. In this paper, we use first principles calculations to test several different mechanisms for determining whether a given substrate-film pair will successfully be grown with remote epitaxy. We find that previously calculated metrics such as electrostatic potential do not hold sufficient explanatory power. We find that the sliding barrier of small islands on the surface when the atomic positions are allowed to optimize provides the most rigorous criteria for whether a given substrate-film pair is remote epitaxy active. This indicates that remote epitaxy is likely a phenomenon related to the kinetics and ease of island migration on the graphene surface.
title Island Sliding Barriers: A first-principles metric for determining remote epitaxy viability
topic Materials Science
url https://arxiv.org/abs/2603.10968