Related papers: Intermediate Excited State Relaxation Dynamics of Boron-Vacancy Spin Defects in Hexagonal Boron Nitride

Intermediate Excited State Relaxation Dynamics of Boron-Vacancy Spin Defects in Hexagonal Boron Nitride

URL: http://arxiv.org/abs/2503.22815v1
Date: Fri, 28 Mar 2025 18:23:07 GMT
Title: Intermediate Excited State Relaxation Dynamics of Boron-Vacancy Spin Defects in Hexagonal Boron Nitride
Authors: Paul Konrad, Mehran Kianinia, Lesley Spencer, Andreas Sperlich, Lukas Hein, Selin Steinicke, Igor Aharonovich, Vladimir Dyakonov,
Abstract summary: We investigate the dynamics of the excited and intermediate states in the optical cycle under pulsed laser excitation in a broad temperature range.<n>Experiments show a relaxation time of 24 ns from the metastable state back to the ground state at room temperature.<n>We optimize pulsed optically detected magnetic resonance sequences to account for the relaxation of the intermediate state.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The experimental identification of optically addressable spin defects in hexagonal boron nitride has opened new possibilities for quantum sensor technologies in two-dimensional materials and structures. Despite numerous fundamental and theoretical studies on the electronic structure of defects, the dynamics of the excited states are yet to be comprehensively investigated. The non-radiative relaxation pathways from the triplet excited states to the triplet ground states, particularly the one via a metastable intermediate state, remain largely presumed. A detailed identification, let alone a direct measurement of the rate constants, is still lacking. In this work, we investigate the relaxation dynamics of the excited and intermediate states in the optical cycle under pulsed laser excitation in a broad temperature range. The focus is on the shelving intermediate state and resulting ground state spin polarization of an ensemble of optically pumped negatively charged boron vacancies. Our experiments show a relaxation time of 24 ns from the metastable state back to the ground state at room temperature. For low temperatures we find this time to approximately double - in accordance with a doubling of photoluminescence lifetime and intensity. Simulations show the evolution of the spin-populations in the five-level system and the polarization of the ground state depending on excitation rates. We thus optimize pulsed optically detected magnetic resonance sequences to account for the relaxation of the intermediate state. This yields significantly increased efficiency of the spin manipulation and hence, the sensitivity of the quantum sensor based on boron vacancies can be optimized considerably.

Related papers

Signatures of collective photon emission and ferroelectric ordering of excitons near their Mott insulating state in a WSe$_2$/WS$_2$ heterobilayer [5.513261477879772]
We present evidence for an in-plane ferroelectric phase of dipolar moir'e excitons driven by strong exciton-exciton interactions.<n>We discover a surprising speed-up of photon emission at late times and low densities in excitonic decay.<n>Our findings provide first evidence for strong dipolar inter-site interactions in moir'e lattices, demonstrate collective photon emission as a probe for moir'e quantum materials.
arXiv Detail & Related papers (2025-02-26T19:00:09Z)
Dissipative stabilization of maximal entanglement between non-identical emitters via two-photon excitation [49.1574468325115]
Two non-identical quantum emitters, when placed within a cavity and coherently excited at the two-photon resonance, can reach stationary states of nearly maximal entanglement. We show that this mechanism is merely one among a complex family of phenomena that can generate both stationary and metastable entanglement when driving the emitters at the two-photon resonance.
arXiv Detail & Related papers (2023-06-09T16:49:55Z)
Analyzing the collective emission of a Rydberg-blockaded single-photon source based on an ensemble of thermal atoms [0.0]
We numerically study the feasibility of a single-photon source in a hot vapor of Rubidium atoms in a micro cell. For the excitation process with three rectangular lasers pulses, we simulate the coherent dynamics of the system in a truncated Hilbert space. We find that the collective decay of the single-excitation leads to a fast and directed photon emission and further, that a pulse sequence similar to a spin echo increases the directionality of the photon.
arXiv Detail & Related papers (2023-03-07T14:43:27Z)
Dynamics of moire trion and its valley polarization in microfabricated WSe2/MoSe2 heterobilayer [0.36944296923226316]
We propose a microfabrication technique based on focused Ga+ ion beams, which enables us to control the number of peaks originating from the moire potential. By taking advantage of this approach, we reveal emissions from a single moire exciton and charged moire exciton (trion) under electrostatic doping conditions.
arXiv Detail & Related papers (2023-01-26T10:02:37Z)
Spin-phonon decoherence in solid-state paramagnetic defects from first principles [79.4957965474334]
Paramagnetic defects in diamond and hexagonal boron nitride possess a unique combination of spin and optical properties that make them solid-state qubits. Despite the coherence of these spin qubits being critically limited by spin-phonon relaxation, a full understanding of this process is not yet available. We demonstrate that low-frequency two-phonon modulations of the zero-field splitting are responsible for spin relaxation and decoherence.
arXiv Detail & Related papers (2022-12-22T13:48:05Z)
Probing dynamics of a two-dimensional dipolar spin ensemble using single qubit sensor [62.997667081978825]
We experimentally investigate individual spin dynamics in a two-dimensional ensemble of electron spins on the surface of a diamond crystal. We show that this anomalously slow relaxation rate is due to the presence of strong dynamical disorder. Our work paves the way towards microscopic study and control of quantum thermalization in strongly interacting disordered spin ensembles.
arXiv Detail & Related papers (2022-07-21T18:00:17Z)
Three-photon excitation of quantum two-level systems [0.0]
We demonstrate that semiconductor quantum dots can be excited efficiently in a resonant three-photon process. Time-dependent Floquet theory is used to quantify the strength of the multi-photon processes. We exploit this technique to probe intrinsic properties of InGaN quantum dots.
arXiv Detail & Related papers (2022-02-04T09:20:24Z)
Visualizing spinon Fermi surfaces with time-dependent spectroscopy [62.997667081978825]
We propose applying time-dependent photo-emission spectroscopy, an established tool in solid state systems, in cold atom quantum simulators. We show in exact diagonalization simulations of the one-dimensional $t-J$ model that the spinons start to populate previously unoccupied states in an effective band structure. The dependence of the spectral function on the time after the pump pulse reveals collective interactions among spinons.
arXiv Detail & Related papers (2021-05-27T18:00:02Z)
Light-matter interactions near photonic Weyl points [68.8204255655161]
Weyl photons appear when two three-dimensional photonic bands with linear dispersion are degenerated at a single momentum point, labeled as Weyl point. We analyze the dynamics of a single quantum emitter coupled to a Weyl photonic bath as a function of its detuning with respect to the Weyl point.
arXiv Detail & Related papers (2020-12-23T18:51:13Z)
Strongly entangled system-reservoir dynamics with multiphoton pulses beyond the two-excitation limit: Exciting the atom-photon bound state [62.997667081978825]
We study the non-Markovian feedback dynamics of a two-level system interacting with the electromagnetic field inside a semi-infinite waveguide. We compare the trapped excitation for an initially excited quantum emitter and an emitter prepared via quantized pulses containing up to four photons.
arXiv Detail & Related papers (2020-11-07T12:56:16Z)
Room Temperature Coherent Control of Spin Defects in hexagonal Boron Nitride [0.0]
Optically active defects in solids with accessible spin states are promising candidates for solid state quantum information and sensing applications. We realize coherent control of ensembles of boron vacancy centers in hexagonal boron nitride (hBN) Our results are important for employment of van der Waals materials for quantum technologies.
arXiv Detail & Related papers (2020-10-23T16:31:37Z)

This list is automatically generated from the titles and abstracts of the papers in this site.