Giant shift upon strain on the fluorescence spectrum of VNNB color centers in h-BN

Song, Li; Chou, Jyh‐Pin; Hu, Alice; Plenio, Martin B.; Udvarhelyi, Péter; Thiering, Gergő; Abdi, Mehdi; Gali, Ádám

doi:10.1038/s41534-020-00312-y

Cited by 40 publications

(39 citation statements)

References 56 publications

(83 reference statements)

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“…Hence, including the effect of substrate surface on the SPEs demands further investigations, which remains an open subject for future studies. We note here that recent calculations on color centers in hexagonal boron nitride have demonstrated that the number of boron nitride layers has minimal effect on the ZPL of the color centers [36]. Similarly, we expect that 2D-SiC monolayers form weak bonds with the substrate, and thus only cause slight modification in the properties of the localized defect states.…”

Section: Resultssupporting

confidence: 49%

“…Another critical effect which lies at the heart of our analysis is the electric dipole interaction that determines dark and bright states. Those states that their dipole moment can couple to the ground state via the external electric field, provided by electromagnetic radiation, determine the selection rules [35,36]. In this part of study, the value of matrix elements ψ|O|φ is vanishing if their total irreducible symmetry is not that of totally symmetric irreducible representation, here A 1 and A for the C 2v and C s , respectively.…”

Section: Methodsmentioning

confidence: 99%

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Theoretical study of quantum emitters in two-dimensional silicon carbide monolayers

et al. 2020

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The electronic and optical features of some potential single-photon sources in two-dimensional silicon carbide monolayers is studied via ab initio calculations and group theory analyses. A few point defects in three charge states (negative, positive, and neutral) are considered. By applying performance criteria, Stone-Wales defects without and with combination of antisite defects are studied in detail. The formation energy calculations reveal that neutral and positive charge states of these defects are stable. We compute the zero-phonon-line energy, the Huang-Rhys (HR) factor, and the photoluminescence spectrum for the available transitions in different charge states. The calculated HR values and the related Debye-Waller factors guarantee that the Stone-Wales defects have a high potential of performing as a promising single-photon emitter.

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Section: Resultssupporting

confidence: 49%

Section: Methodsmentioning

confidence: 99%

Theoretical study of quantum emitters in two-dimensional silicon carbide monolayers

et al. 2020

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“…The ab initio analysis provided in the previous section has allowed us to find the effect of local strain on the energy levels of negatively charged boron vacancy defects (V B ). Our results suggest that the deformation potential for the simulated configuration (a monolayer hBN) becomes as large as Ξ = 2.98 PHz/strain for stretch or compression along the armchair direction, which is in the same order of magnitude that has been previously reported by some of us for the complex antisite defect (V N N B ) in hBN [12]. Such large deformation susceptibility emerges thanks to the two-dimensional nature of the setup and has the potential of leading us to the strong interaction between the vibrational modes and the color centers.…”

Section: B Hamiltonian Of the Systemsupporting

confidence: 85%

“…In the later experiments larger effect of the strain was further revealed by modifying the setup [10,11]. On the theory side, the computational analysis on the effect of strain on the antisite complex defects V N N B , that are counted as one of the main candidates of quantum emission from hBN, proved that the sensitivity of these color centers to the local strain is significant [12]. Meanwhile, there are other point defects responsible for the single-photon emission such as boron vacancy that has shown interesting electronic and magnetic properties such as optical polarization of their ground state [13,14].…”

Section: Introductionmentioning

confidence: 97%

Strain induced coupling and quantum information processing with hexagonal boron nitride quantum emitters

Tabesh,

Hassanzada,

Hadian

et al. 2021

Preprint

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We propose an electromechanical scheme where the electronic degrees of freedom of boron vacancy color centers hosted by a hexagonal boron nitride nanoribbon are coupled for quantum information processing. The mutual coupling of color centers is provided via their coupling to the mechanical motion of the ribbon, which in turn stems from the local strain. The coupling strengths are computed by performing ab initio calculations. The density functional theory (DFT) results for boron vacancy centers on boron nitride monolayers reveal a huge strain susceptibility. In our analysis, we take into account the effect of all flexural modes and show that despite the thermal noise introduced through the vibrations one can achieve steady-state entanglement between two and more number of qubits that survives even at room temperature. Moreover, the entanglement is robust against mis-positioning of the color centers. The effective coupling of color centers is engineered by positioning them in the proper positions. Hence, one is able to tailor stationary graph states. Furthermore, we study the quantum simulation of the Dicke-Ising model and show that the phonon superradiance phase transition occurs even for a finite number of color centers. Given the steady-state nature of the proposed scheme and accessibility of the electronic states through optical fields, our work paves the way for the realization of steady-state quantum information processing with color centers in hexagonal boron nitride membranes.

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“…Technical overhead could be further reduced when the need for cryogenics is eliminated which requires detailed studies of electron-phonon interaction [18][19][20]. Defect centers in hBN show, for example, almost unity quantum efficiency [21], giant strain-induced shift of the zero-phonon-line (ZPL) emission [22] and, in particular, Fourier transform-limited (FTL) optical transitions under resonant excitation at cryogenic temperatures [23] as well as room temperature (RT) [24]. Remaining limitations, for example originating from on-going spectral diffusion and thermally generated phonon interactions under off-resonant excitation are currently investigated and continuously improved [25].…”

Section: Introductionmentioning

confidence: 99%

Single photon randomness originating from the symmetry of dipole emission and the unpredictability of spontaneous emission

Hoese,

Koch,

Breuning

et al. 2021

Preprint

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Quantum random number generation is a key ingredient for quantum cryptography and fundamental quantum optics and could advance Monte-Carlo simulations and machine learning. An established generation scheme is based on single photons impinging on a beam splitter. Here, we experimentally demonstrate quantum random number generation solely based on the spontaneous emission process in combination with the symmetric emission profile of a dipole aligned orthogonal to the laboratory frame. The demonstration builds on defect centers in hexagonal boron nitride and benefits from the ability to manipulate and align the emission directionality. We prove the randomness in the correlated photon detection events making use of the NIST randomness test suite and show that the randomness remains for two independently emitting defect centers. The scheme can be extended to random number generation by coherent single photons with potential applications in solid-state based quantum communication at room temperature.

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Giant shift upon strain on the fluorescence spectrum of VNNB color centers in h-BN

Cited by 40 publications

References 56 publications

Theoretical study of quantum emitters in two-dimensional silicon carbide monolayers

Theoretical study of quantum emitters in two-dimensional silicon carbide monolayers

Strain induced coupling and quantum information processing with hexagonal boron nitride quantum emitters

Single photon randomness originating from the symmetry of dipole emission and the unpredictability of spontaneous emission

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