Probing Electric-Dipole-Enabled Transitions in the Excited State of the Nitrogen-Vacancy Center in Diamond

Tom Delord; Richard Monge; Gabriel I. López-Morales; Olaf Bach; Cyrus E. Dreyer; Johannes Flick; Carlos A. Meriles

doi:10.1103/hp9c-rh23

Probing Electric-Dipole-Enabled Transitions in the Excited State of the Nitrogen-Vacancy Center in Diamond

Tom Delord
, Richard Monge
, Gabriel I. López-Morales
, Olaf Bach
, Cyrus E. Dreyer
, Johannes Flick
, Carlos A. Meriles

City University of New York
Stony Brook University
Simons Foundation

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

1 Scopus citations

Abstract

The excited orbitals of color centers often show strong electric dipoles, which can serve as a resource for entanglement, emission tuning, or electric field sensing. Here, we use resonant laser excitation to examine the electric transitions in the excited state (ES) orbitals of the negatively charged nitrogen vacancy center in diamond. By applying microwave electric fields, we perform Rabi driving between ES orbitals, and show that the dressed states can be tuned in frequency and are protected against fluctuations of the transverse electric field. In contrast with previous results, we observe sharp microwave resonances between magnetic states of the ES orbitals, and find that they are broadened due to simultaneous electric dipole driving.

Original language	English
Article number	226401
Journal	Physical Review Letters
Volume	135
Issue number	22
DOIs	https://doi.org/10.1103/hp9c-rh23
State	Published - Nov 26 2025

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10.1103/hp9c-rh23

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title = "Probing Electric-Dipole-Enabled Transitions in the Excited State of the Nitrogen-Vacancy Center in Diamond",

abstract = "The excited orbitals of color centers often show strong electric dipoles, which can serve as a resource for entanglement, emission tuning, or electric field sensing. Here, we use resonant laser excitation to examine the electric transitions in the excited state (ES) orbitals of the negatively charged nitrogen vacancy center in diamond. By applying microwave electric fields, we perform Rabi driving between ES orbitals, and show that the dressed states can be tuned in frequency and are protected against fluctuations of the transverse electric field. In contrast with previous results, we observe sharp microwave resonances between magnetic states of the ES orbitals, and find that they are broadened due to simultaneous electric dipole driving.",

author = "Tom Delord and Richard Monge and L{\'o}pez-Morales, \{Gabriel I.\} and Olaf Bach and Dreyer, \{Cyrus E.\} and Johannes Flick and Meriles, \{Carlos A.\}",

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T1 - Probing Electric-Dipole-Enabled Transitions in the Excited State of the Nitrogen-Vacancy Center in Diamond

AU - Delord, Tom

AU - Monge, Richard

AU - López-Morales, Gabriel I.

AU - Bach, Olaf

AU - Dreyer, Cyrus E.

AU - Flick, Johannes

AU - Meriles, Carlos A.

PY - 2025/11/26

Y1 - 2025/11/26

N2 - The excited orbitals of color centers often show strong electric dipoles, which can serve as a resource for entanglement, emission tuning, or electric field sensing. Here, we use resonant laser excitation to examine the electric transitions in the excited state (ES) orbitals of the negatively charged nitrogen vacancy center in diamond. By applying microwave electric fields, we perform Rabi driving between ES orbitals, and show that the dressed states can be tuned in frequency and are protected against fluctuations of the transverse electric field. In contrast with previous results, we observe sharp microwave resonances between magnetic states of the ES orbitals, and find that they are broadened due to simultaneous electric dipole driving.

AB - The excited orbitals of color centers often show strong electric dipoles, which can serve as a resource for entanglement, emission tuning, or electric field sensing. Here, we use resonant laser excitation to examine the electric transitions in the excited state (ES) orbitals of the negatively charged nitrogen vacancy center in diamond. By applying microwave electric fields, we perform Rabi driving between ES orbitals, and show that the dressed states can be tuned in frequency and are protected against fluctuations of the transverse electric field. In contrast with previous results, we observe sharp microwave resonances between magnetic states of the ES orbitals, and find that they are broadened due to simultaneous electric dipole driving.

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VL - 135

JO - Physical Review Letters

JF - Physical Review Letters

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M1 - 226401

ER -

Probing Electric-Dipole-Enabled Transitions in the Excited State of the Nitrogen-Vacancy Center in Diamond

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