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Autores principales: Peña, Luis Fabián, Brickson, Mitchell I., Rovaris, Fabrizio, Dycus, J. Houston, McDonald, Anthony, Piontkowski, Zachary T., Ruzindana, Joel Benjamin, Bradicich, Adelaide M., Bethke, Don, Scott, Robin, Beechem, Thomas E., Montalenti, Francesco, Jacobson, N. Tobias, Bussmann, Ezra
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2601.05553
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author Peña, Luis Fabián
Brickson, Mitchell I.
Rovaris, Fabrizio
Dycus, J. Houston
McDonald, Anthony
Piontkowski, Zachary T.
Ruzindana, Joel Benjamin
Bradicich, Adelaide M.
Bethke, Don
Scott, Robin
Beechem, Thomas E.
Montalenti, Francesco
Jacobson, N. Tobias
Bussmann, Ezra
author_facet Peña, Luis Fabián
Brickson, Mitchell I.
Rovaris, Fabrizio
Dycus, J. Houston
McDonald, Anthony
Piontkowski, Zachary T.
Ruzindana, Joel Benjamin
Bradicich, Adelaide M.
Bethke, Don
Scott, Robin
Beechem, Thomas E.
Montalenti, Francesco
Jacobson, N. Tobias
Bussmann, Ezra
contents SiGe heterostructures integrated with Si via virtual substrate (VS) growth are promising hosts for spin qubits. While VS growth targets plastic relaxation, residual cross-hatch strain inhomogeneity propagates into heterostructure overgrowth. To quantify strain inhomogeneity's influence on interface structure and qubit properties, we measure strained-silicon (s-Si)/Si$_{0.7}$Ge$_{0.3}$ heterostructures on 25 wafers processed via standard commercial chemical vapor deposition. Spatially-aligned images of strain (Raman microscopy) and interface structure (atomic force microscopy and cross-sectional scanning transmission electron microscopy) reveal strain-roughness interplay. A strain-driven surface diffusion model predicts the roughness and its temperature dependence. Measured strains suggest spurious double-dot qubit detunings of 0.1 meV over 100 nm distances may result. Modeling shows that interface roughness (atomic steps), when convolved with alloy disorder, only modestly reduces valley splitting (70$\pm$13 vs. 77$\pm$14 $μ$eV on average). Our findings point to thicker VS buffer layers beneath heterostructures and lower-temperature growth (T $\le$ 700 $^{\circ}$C) to limit roughening.
format Preprint
id arxiv_https___arxiv_org_abs_2601_05553
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Cross-hatch strain effects on SiGe quantum dots for qubit variability estimation
Peña, Luis Fabián
Brickson, Mitchell I.
Rovaris, Fabrizio
Dycus, J. Houston
McDonald, Anthony
Piontkowski, Zachary T.
Ruzindana, Joel Benjamin
Bradicich, Adelaide M.
Bethke, Don
Scott, Robin
Beechem, Thomas E.
Montalenti, Francesco
Jacobson, N. Tobias
Bussmann, Ezra
Materials Science
SiGe heterostructures integrated with Si via virtual substrate (VS) growth are promising hosts for spin qubits. While VS growth targets plastic relaxation, residual cross-hatch strain inhomogeneity propagates into heterostructure overgrowth. To quantify strain inhomogeneity's influence on interface structure and qubit properties, we measure strained-silicon (s-Si)/Si$_{0.7}$Ge$_{0.3}$ heterostructures on 25 wafers processed via standard commercial chemical vapor deposition. Spatially-aligned images of strain (Raman microscopy) and interface structure (atomic force microscopy and cross-sectional scanning transmission electron microscopy) reveal strain-roughness interplay. A strain-driven surface diffusion model predicts the roughness and its temperature dependence. Measured strains suggest spurious double-dot qubit detunings of 0.1 meV over 100 nm distances may result. Modeling shows that interface roughness (atomic steps), when convolved with alloy disorder, only modestly reduces valley splitting (70$\pm$13 vs. 77$\pm$14 $μ$eV on average). Our findings point to thicker VS buffer layers beneath heterostructures and lower-temperature growth (T $\le$ 700 $^{\circ}$C) to limit roughening.
title Cross-hatch strain effects on SiGe quantum dots for qubit variability estimation
topic Materials Science
url https://arxiv.org/abs/2601.05553