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Your search keyword '"Puel, Tharnier O."' showing total 9 results
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9 results on '"Puel, Tharnier O."'

1. Ab initio calculations of erbium crystal field splittings in oxide hosts: role of the 4f radial wave function

Author

Limbu, Yogendra, Shi, Yueguang, Sink, Joseph, Puel, Tharnier O., Paudyal, Durga, and Flatté, Michael E.

Subjects
Condensed Matter - Materials Science, Quantum Physics
Abstract

We expand here our description of a newly developed simple and effective ab initio method of calculating crystal field coefficients (CFCs) of rare-earth atoms in insulating hosts, focusing on Er in wide band gap oxide hosts MgO, ZnO, TiO$_2$, CaWO$_4$, and PbWO$_4$, which exemplify different local site symmetries. These hybrid functional calculations, which incorporate a portion of exact exchange from Hartree-Fock theory, reproduce the experimentally identified insulating band gaps of these oxides. The negative values of cohesive and formation energies confirm the structural and chemical stability of these oxides, whereas the defect formation energies indicate that Er doped ZnO, CaWO$_4$, and PbWO$_4$ are easier to form compared to Er doped MgO and TiO$_2$. Er doped in these oxide hosts exhibits a spin magnetic moment of $\sim$ 3 $\mu_B$ confirming the $3+$ valence state. The CFCs of these hosted Er are determined from charge densities and potentials obtained from non-spin-polarized calculations, involving a 4\textit{f} core approximation. These CFCs are subsequently used to solve an effective Hamiltonian and generate the crystal field splitting of Er 4f. These calculated Er 4f energy levels are in good agreement with available experiments.

Published
2025

2. Ab initio calculations of erbium crystal field splittings in oxide hosts

Author

Limbu, Yogendra, Shi, Yueguang, Sink, Joseph, Puel, Tharnier O., Paudyal, Durga, and Flatté, Michael E.

Subjects
Condensed Matter - Materials Science, Quantum Physics
Abstract

We present an effective ab initio method to calculate the crystal field coefficients of an erbium (Er3+) ion experiencing different local site symmetries in several wide-band-gap oxides, and then evaluate crystal field splittings of these Er3+ ions for their ground and excited states. The optical transitions between the ground state (Z) and excited state (Y) manifolds of the environmentally shielded 4f states of these Er3+ ions have wavelengths ~1.5 microns and thus have potential applications to quantum communications and quantum memories. These results are in excellent agreement with recent low-temperature measurements, provided the inadequate calculation of the 4f shell screening is adjusted by reducing the radial extent of the 4f wavefunctions by approximately a factor of 2.

Published
2025

3. Enhancement of Microwave to Optical Spin-Based Quantum Transduction via a Magnon Mode

Author

Puel, Tharnier O., Turflinger, Adam T., Horvath, Sebastian P., Thompson, Jeff D., and Flatté, Michael E.

Subjects
Quantum Physics
Abstract

We propose a new method for converting single microwave photons to single optical sideband photons based on spinful impurities in magnetic materials. This hybrid system is advantageous over previous proposals because (i) the implementation allows much higher transduction rates ($10^{3}$ times faster at the same optical pump Rabi frequency) than state-of the art devices, (ii) high-efficiency transduction is found to happen in a significantly larger space of device parameters (in particular, over $1$ GHz microwave detuning), and (iii) it does not require mode volume matching between optical and microwave resonators. We identify the needed magnetic interactions as well as potential materials systems to enable this speed-up using erbium dopants for telecom compatibility. This is an important step towards realizing high-fidelity entangling operations between remote qubits and will provide additional control of the transduction through perturbation of the magnet., Comment: 3 figures, 12 pages including supplementary material

Published
2024

4. Confined Meson Excitations in Rydberg-Atom Arrays Coupled to a Cavity Field

Author

Puel, Tharnier O. and Macrì, Tommaso

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Other Condensed Matter, Quantum Physics
Abstract

Confinement is a pivotal phenomenon in numerous models of high-energy and statistical physics. In this study, we investigate the emergence of confined meson excitations within a one-dimensional system, comprising Rydberg-dressed atoms trapped and coupled to a cavity field. This system can be effectively represented by an Ising-Dicke Hamiltonian model. The observed ground-state phase diagram reveals a first-order transition from a ferromagnetic-subradiant phase to a paramagnetic-superradiant phase. Notably, a quench near the transition point within the ferromagnetic-subradiant phase induces meson oscillations in the spins and leads to the creation of squeezed-vacuum light states. We suggest a method for the photonic characterization of these confined excitations, utilizing homodyne detection and single-site imaging techniques to observe the localized particles. The methodologies and results detailed in this paper are feasible for implementation on existing cavity-QED platforms, employing Rydberg-atom arrays in deep optical lattices or optical tweezers., Comment: 13 pages, 8 figures, including supplemental material

Published
2023
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5. Strong photon-magnon coupling using a lithographically defined organic ferrimagnet

Author

Xu, Qin, Cheung, Hil Fung Harry, Cormode, Donley S., Puel, Tharnier O., Yusuf, Huma, Chilcote, Michael, Flatté, Michael E., Johnston-Halperin, Ezekiel, and Fuchs, Gregory D.

Subjects
Quantum Physics, Condensed Matter - Materials Science
Abstract

We demonstrate a hybrid quantum system composed of superconducting resonator photons and magnons hosted by the organic-based ferrimagnet vanadium tetracyanoethylene (V[TCNE]$_x$). Our work is motivated by the challenge of scalably integrating an arbitrarily-shaped, low-damping magnetic system with planar superconducting circuits, thus enabling a host of quantum magnonic circuit designs that were previously inaccessible. For example, by leveraging the inherent properties of magnons, one can enable nonreciprocal magnon-mediated quantum devices that use magnon propagation rather than electrical current. We take advantage of the properties of V[TCNE]$_x$, which has ultra-low intrinsic damping, can be grown at low processing temperatures on arbitrary substrates, and can be patterned via electron beam lithography. We demonstrate the scalable, lithographically integrated fabrication of hybrid quantum magnonic devices consisting of a thin-film superconducting resonator coupled to a low-damping, thin-film V[TCNE]$_x$ microstructure. Our devices operate in the strong coupling regime, with a cooperativity as high as 1181(44) at T$\sim$0.4 K, suitable for scalable quantum circuit integration. This work paves the way for the exploration of high-cooperativity hybrid magnonic quantum devices in which magnonic circuits can be designed and fabricated as easily as electrical wires., Comment: 31 pages preprint format with supplementary materials

Published
2022

6. Nonequilibrium phases and phase transitions of the XY-model

Author

Puel, Tharnier O., Chesi, Stefano, Kirchner, Stefan, and Ribeiro, Pedro

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons, Quantum Physics
Abstract

We obtain the steady-state phase diagram of a transverse field XY spin chain coupled at its ends to magnetic reservoirs held at different magnetic potentials. In the long-time limit, the magnetization bias across the system generates a current-carrying non-equilibrium steady-state. We characterize the different non-equilibrium phases as functions of the chain's parameters and magnetic potentials, in terms of their correlation functions and entanglement content. The mixed-order transition, recently observed for the particular case of a transverse field Ising chain, is established to emerge as a generic out-of-equilibrium feature and its critical exponents are determined analytically. Results are also contrasted with those obtained in the limit of Markovian reservoirs. Our findings should prove helpful in establishing the properties of non-equilibrium phases and phase transitions of extended open quantum systems., Comment: 16 pages, 14 figures

Published
2020
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8. Strong Photon‐Magnon Coupling Using a Lithographically Defined Organic Ferrimagnet.

Author

Xu, Qin, Cheung, Hil Fung Harry, Cormode, Donley S., Puel, Tharnier O., Pal, Srishti, Yusuf, Huma, Chilcote, Michael, Flatté, Michael E., Johnston‐Halperin, Ezekiel, and Fuchs, Gregory D.

Subjects
ELECTRON beam lithography, SUPERCONDUCTING resonators, SUPERCONDUCTING circuits, TETRACYANOETHYLENE
Abstract

A cavity‐magnonic system composed of a superconducting microwave resonator coupled to a magnon mode hosted by the organic‐based ferrimagnet vanadium tetracyanoethylene (V[TCNE]x) is demonstrated. This work is motivated by the challenge of scalably integrating a low‐damping magnetic system with planar superconducting circuits. V[TCNE]x has ultra‐low intrinsic damping, can be grown at low processing temperatures on arbitrary substrates, and can be patterned via electron beam lithography. The devices operate in the strong coupling regime, with a cooperativity exceeding 1000 for coupling between the Kittel mode and the resonator mode at T≈0.4 K, suitable for scalable quantum circuit integration. Higher‐order magnon modes are also observed with much narrower linewidths than the Kittel mode. This work paves the way for high‐cooperativity hybrid quantum devices in which magnonic circuits can be designed and fabricated as easily as electrical wires. [ABSTRACT FROM AUTHOR]

Published
2024
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