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Main Authors: deQuilettes, Dane W., Price, Eden, Pham, Linh M., Kurlej, Arthur, Vattam, Swaroop, Melville, Alexander, Osadchy, Tom, Li, Boning, Wang, Guoqing, Muniz, Collin N., Cappellaro, Paola, Schloss, Jennifer M., Mallek, Justin L., Braje, Danielle A.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.22121
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author deQuilettes, Dane W.
Price, Eden
Pham, Linh M.
Kurlej, Arthur
Vattam, Swaroop
Melville, Alexander
Osadchy, Tom
Li, Boning
Wang, Guoqing
Muniz, Collin N.
Cappellaro, Paola
Schloss, Jennifer M.
Mallek, Justin L.
Braje, Danielle A.
author_facet deQuilettes, Dane W.
Price, Eden
Pham, Linh M.
Kurlej, Arthur
Vattam, Swaroop
Melville, Alexander
Osadchy, Tom
Li, Boning
Wang, Guoqing
Muniz, Collin N.
Cappellaro, Paola
Schloss, Jennifer M.
Mallek, Justin L.
Braje, Danielle A.
contents Spins in solid-state materials, molecules, and other chemical systems have the potential to impact the fields of quantum sensing, communication, simulation, and computing. In particular, color centers in diamond, such as negatively charged nitrogen vacancy (NV$^-$) and silicon vacancy centers (SiV$^-$), are emerging as quantum platforms poised for transition to commercial devices. A key enabler stems from the semiconductor-like platform that can be tailored at the time of growth. The large growth parameter space makes it challenging to use intuition to optimize growth conditions for quantum performance. In this paper, we use supervised machine learning to train regression models using different synthesis parameters in over 100 quantum diamond samples. We train models to optimize NV$^-$ defects in diamond for high sensitivity magnetometry. Importantly, we utilize a magnetic-field sensitivity figure of merit (FOM) for NV magnetometry and use Bayesian optimization to identify critical growth parameters that lead to a 300% improvement over an average sample and a 55% improvement over the previous champion sample. Furthermore, using Shapley importance rankings, we gain new physical insights into the most impactful growth and post-processing parameters, namely electron irradiation dose, diamond seed depth relative to the plasma, seed miscut angle, and reactor nitrogen concentration. As various quantum devices can have significantly different material requirements, advanced growth techniques such as plasma-enhanced chemical vapor deposition (PE-CVD) can provide the ability to tailor material development specifically for quantum applications.
format Preprint
id arxiv_https___arxiv_org_abs_2510_22121
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Machine Learning Enables Optimization of Diamond for Quantum Applications
deQuilettes, Dane W.
Price, Eden
Pham, Linh M.
Kurlej, Arthur
Vattam, Swaroop
Melville, Alexander
Osadchy, Tom
Li, Boning
Wang, Guoqing
Muniz, Collin N.
Cappellaro, Paola
Schloss, Jennifer M.
Mallek, Justin L.
Braje, Danielle A.
Materials Science
Quantum Physics
Spins in solid-state materials, molecules, and other chemical systems have the potential to impact the fields of quantum sensing, communication, simulation, and computing. In particular, color centers in diamond, such as negatively charged nitrogen vacancy (NV$^-$) and silicon vacancy centers (SiV$^-$), are emerging as quantum platforms poised for transition to commercial devices. A key enabler stems from the semiconductor-like platform that can be tailored at the time of growth. The large growth parameter space makes it challenging to use intuition to optimize growth conditions for quantum performance. In this paper, we use supervised machine learning to train regression models using different synthesis parameters in over 100 quantum diamond samples. We train models to optimize NV$^-$ defects in diamond for high sensitivity magnetometry. Importantly, we utilize a magnetic-field sensitivity figure of merit (FOM) for NV magnetometry and use Bayesian optimization to identify critical growth parameters that lead to a 300% improvement over an average sample and a 55% improvement over the previous champion sample. Furthermore, using Shapley importance rankings, we gain new physical insights into the most impactful growth and post-processing parameters, namely electron irradiation dose, diamond seed depth relative to the plasma, seed miscut angle, and reactor nitrogen concentration. As various quantum devices can have significantly different material requirements, advanced growth techniques such as plasma-enhanced chemical vapor deposition (PE-CVD) can provide the ability to tailor material development specifically for quantum applications.
title Machine Learning Enables Optimization of Diamond for Quantum Applications
topic Materials Science
Quantum Physics
url https://arxiv.org/abs/2510.22121