Optically Detected Magnetic Resonance on Carbene Molecular Qubits

Simon Roggors; Nico Striegler; Thomas Unden; Oleksiy Khavryuchenko; Alon Salhov; Jochen Scharpf; Martin B. Plenio; Alex Retzker; Fedor Jelezko; Matthias Pfender; Philipp Neumann; Tim R. Eichhorn; Tobias A. Schaub; Ilai Schwartz

doi:10.1021/jacs.5c10272

Optically Detected Magnetic Resonance on Carbene Molecular Qubits

Simon Roggors
, Nico Striegler
, Thomas Unden
, Oleksiy Khavryuchenko
, Alon Salhov
, Jochen Scharpf
, Martin B. Plenio
, Alex Retzker
, Fedor Jelezko
, Matthias Pfender
, Philipp Neumann
, Tim R. Eichhorn
, Tobias A. Schaub^*
, Ilai Schwartz^*

^*Corresponding author for this work

Racah Institute of Physics

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

6 Scopus citations

Abstract

Solid-state quantum systems with optical and spin degrees of freedom have found widespread application in emerging quantum technologies. Recently, molecular qubits came forward as precisely tunable entities that present a compelling alternative to well-established yet hard-to-tune point defects in solid-state systems. In this work, we disclose ground-state triplet carbenes as purely organic qubits comprising two unpaired electrons in close proximity that can be generated in a crystalline matrix with high spatial accuracy via in situ photoactivation. We further demonstrate how state-of-the-art multireference quantum chemical calculations provide insight into their fundamental spin characteristics. As a result, several key assets were realized in a single solid-state qubit material under cryogenic conditions: The exclusive use of light elements (C, H, N, O), photolithographic patterning, optical spin-selective transitions, and a large zero-field splitting in the GHz regime, which, taken together, lays the ground for optically detected magnetic resonance with remarkable fluorescence contrast of >40% and record-high spin coherence times of T₂= 157(4) μs at 5 K.

Original language	English
Pages (from-to)	36383-36392
Number of pages	10
Journal	Journal of the American Chemical Society
Volume	147
Issue number	40
DOIs	https://doi.org/10.1021/jacs.5c10272
State	Published - 8 Oct 2025

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Publisher Copyright:
© 2025 The Authors. Published by American Chemical Society

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Roggors, S., Striegler, N., Unden, T., Khavryuchenko, O., Salhov, A., Scharpf, J., Plenio, M. B., Retzker, A., Jelezko, F., Pfender, M., Neumann, P., Eichhorn, T. R., Schaub, T. A., & Schwartz, I. (2025). Optically Detected Magnetic Resonance on Carbene Molecular Qubits. Journal of the American Chemical Society, 147(40), 36383-36392. https://doi.org/10.1021/jacs.5c10272

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title = "Optically Detected Magnetic Resonance on Carbene Molecular Qubits",

abstract = "Solid-state quantum systems with optical and spin degrees of freedom have found widespread application in emerging quantum technologies. Recently, molecular qubits came forward as precisely tunable entities that present a compelling alternative to well-established yet hard-to-tune point defects in solid-state systems. In this work, we disclose ground-state triplet carbenes as purely organic qubits comprising two unpaired electrons in close proximity that can be generated in a crystalline matrix with high spatial accuracy via in situ photoactivation. We further demonstrate how state-of-the-art multireference quantum chemical calculations provide insight into their fundamental spin characteristics. As a result, several key assets were realized in a single solid-state qubit material under cryogenic conditions: The exclusive use of light elements (C, H, N, O), photolithographic patterning, optical spin-selective transitions, and a large zero-field splitting in the GHz regime, which, taken together, lays the ground for optically detected magnetic resonance with remarkable fluorescence contrast of >40\% and record-high spin coherence times of T2= 157(4) μs at 5 K.",

author = "Simon Roggors and Nico Striegler and Thomas Unden and Oleksiy Khavryuchenko and Alon Salhov and Jochen Scharpf and Plenio, \{Martin B.\} and Alex Retzker and Fedor Jelezko and Matthias Pfender and Philipp Neumann and Eichhorn, \{Tim R.\} and Schaub, \{Tobias A.\} and Ilai Schwartz",

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doi = "10.1021/jacs.5c10272",

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AU - Roggors, Simon

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AU - Unden, Thomas

AU - Khavryuchenko, Oleksiy

AU - Salhov, Alon

AU - Scharpf, Jochen

AU - Plenio, Martin B.

AU - Retzker, Alex

AU - Jelezko, Fedor

AU - Pfender, Matthias

AU - Neumann, Philipp

AU - Eichhorn, Tim R.

AU - Schaub, Tobias A.

AU - Schwartz, Ilai

PY - 2025/10/8

Y1 - 2025/10/8

N2 - Solid-state quantum systems with optical and spin degrees of freedom have found widespread application in emerging quantum technologies. Recently, molecular qubits came forward as precisely tunable entities that present a compelling alternative to well-established yet hard-to-tune point defects in solid-state systems. In this work, we disclose ground-state triplet carbenes as purely organic qubits comprising two unpaired electrons in close proximity that can be generated in a crystalline matrix with high spatial accuracy via in situ photoactivation. We further demonstrate how state-of-the-art multireference quantum chemical calculations provide insight into their fundamental spin characteristics. As a result, several key assets were realized in a single solid-state qubit material under cryogenic conditions: The exclusive use of light elements (C, H, N, O), photolithographic patterning, optical spin-selective transitions, and a large zero-field splitting in the GHz regime, which, taken together, lays the ground for optically detected magnetic resonance with remarkable fluorescence contrast of >40% and record-high spin coherence times of T2= 157(4) μs at 5 K.

AB - Solid-state quantum systems with optical and spin degrees of freedom have found widespread application in emerging quantum technologies. Recently, molecular qubits came forward as precisely tunable entities that present a compelling alternative to well-established yet hard-to-tune point defects in solid-state systems. In this work, we disclose ground-state triplet carbenes as purely organic qubits comprising two unpaired electrons in close proximity that can be generated in a crystalline matrix with high spatial accuracy via in situ photoactivation. We further demonstrate how state-of-the-art multireference quantum chemical calculations provide insight into their fundamental spin characteristics. As a result, several key assets were realized in a single solid-state qubit material under cryogenic conditions: The exclusive use of light elements (C, H, N, O), photolithographic patterning, optical spin-selective transitions, and a large zero-field splitting in the GHz regime, which, taken together, lays the ground for optically detected magnetic resonance with remarkable fluorescence contrast of >40% and record-high spin coherence times of T2= 157(4) μs at 5 K.

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Optically Detected Magnetic Resonance on Carbene Molecular Qubits

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