Related papers: Floquet theory and computational method for the optical absorption of laser-dressed solids

Floquet theory and computational method for the optical absorption of laser-dressed solids

URL: http://arxiv.org/abs/2305.09808v2
Date: Thu, 3 Aug 2023 17:54:08 GMT
Title: Floquet theory and computational method for the optical absorption of laser-dressed solids
Authors: Vishal Tiwari, Bing Gu, and Ignacio Franco
Abstract summary: We develop a theory that enables modeling and interpreting the linear optical absorption of solids. The theory applies to any crystalline solid and quantum materials. We implement the theoretical framework into a code FloqticS: Floquet optics in Solids.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Recent advances in laser technology now enable engineering the electronic structure of matter through strong light-matter interactions. However, the effective physicochemical properties of these laser-dressed nonequilibrium materials are not well understood. Here we develop a general theory that now enables modeling and interpreting the linear optical absorption of solids that are dressed by light of arbitrary strength and photon energy. The theory applies to any crystalline solid and quantum materials. In the theory, the dressing of Bloch electrons by the driving laser is treated exactly using Floquet theory. The effective optical properties of this laser-dressed material are probed through a weak laser whose effects are captured to first order in perturbation theory. Remarkably, in this nonequilibrium system the time- and space-periodic Floquet-Bloch modes play the role of the pristine eigenstates of matter as the optical absorption is seen to emerge from transitions among them. We implement the theoretical framework into a code FloqticS: Floquet optics in Solids) available through Github. To isolate the emergent phenomenology, we performed computations in a model solid with a cosine-shaped lattice potential driven by strong nonresonant light. The computations recover the dynamical Franz-Keldysh effect and identify novel dramatic changes in the optical absorption upon increasing the amplitude of the driving laser. The Floquet replicas open absorption sidebands separated by integer multiples of the drive photon energy. The hybridization of the Floquet-Bloch modes, create intense low-frequency absorption and stimulated emissions, and dips in the absorption spectrum. We assign these emerging effects as purely-optical tell-tale signatures of the Floquet-Bloch modes. These advances can be used to model, control and characterize the response properties of laser-dressed materials.

Related papers

Nonclassical Driven-Dissipative Dynamics in Collective Quantum Optics [51.56484100374058]
We study ensembles of interacting quantum emitters coherently driven by a laser field and coupled to photonic structures.<n>We find that off-resonant virtual states may gain population through dissipation, redefining their role in open systems.<n>Our models address challenges like inhomogeneous broadening and decoherence, demonstrating the feasibility of harnessing cooperative light-matter effects for quantum technologies.
arXiv Detail & Related papers (2025-09-12T20:01:55Z)
Cavity-QED-controlled two-dimensional Moiré Excitons without twisting [0.0]
We propose an all-optical Moir'e-like exciton confinement by means of spatially periodic optical cavities.<n>We find that in the classical limit of a laser driven cavity the induced optical confinement directly emulates Moir'e physics.<n>We attribute these effects to long-range cavity-mediated exciton-exciton interactions which can only be captured in a non-perturbative treatment.
arXiv Detail & Related papers (2025-08-04T13:10:55Z)
Robust purely optical signatures of Floquet-Bloch states in crystals [0.0]
Floquet-Bloch states have emerged as the natural states to characterize non-equilibrium systems. Here, we identify a tell-tale signature of Floquet-Bloch states in the linear optical response of laser-dressed solids. The computations reveal intense, spectrally isolated, absorption/stimulated emission features at mid-infrared energies.
arXiv Detail & Related papers (2025-01-28T17:28:28Z)
When do molecular polaritons behave like optical filters? [1.9410328648791897]
This review outlines several linear optical effects featured by molecular polaritons arising in the collective strong light-matter coupling regime.<n>We show that the excited-state molecular dynamics can be exactly replicated without the cavity using a shaped laser.<n>The absorption within a cavity can be understood as the overlap between the polariton transmission and the bare molecular absorption, suggesting that polaritons act in part as optical filters.
arXiv Detail & Related papers (2024-08-09T12:48:34Z)
Photon bunching in high-harmonic emission controlled by quantum light [0.0]
Recent theories have laid the groundwork for understanding how quantum-optical properties affect high-field photonics. We demonstrate a new experimental approach that transduces some properties of a quantum-optical state through a strong-field nonlinearity. Our results suggest that perturbing strong-field dynamics with quantum-optical states is a viable way to coherently control the generation of these states at short wavelengths.
arXiv Detail & Related papers (2024-04-08T12:53:42Z)
All-optical modulation with single-photons using electron avalanche [69.65384453064829]
We demonstrate all-optical modulation using a beam with single-photon intensity. Our approach opens up the possibility of terahertz-speed optical switching at the single-photon level.
arXiv Detail & Related papers (2023-12-18T20:14:15Z)
Directional spontaneous emission in photonic crystal slabs [49.1574468325115]
Spontaneous emission is a fundamental out-of-equilibrium process in which an excited quantum emitter relaxes to the ground state due to quantum fluctuations. One way to modify these photon-mediated interactions is to alter the dipole radiation patterns of the emitter, e.g., by placing photonic crystals near them. Our study delves into the interaction between these directional emission patterns and the aforementioned variables, revealing the untapped potential to fine-tune collective quantum optical phenomena.
arXiv Detail & Related papers (2023-12-04T15:35:41Z)
The maximum refractive index of an atomic crystal $\unicode{x2013}$ from quantum optics to quantum chemistry [52.77024349608834]
We investigate the index of an ordered arrangement of atoms, as a function of atomic density. In quantum optics, we show that ideal light-matter interactions can have a single-mode nature. At the onset of quantum chemistry, we show how two physical mechanisms can open up inelastic or spatial multi-mode light scattering processes.
arXiv Detail & Related papers (2023-03-20T10:29:12Z)
Multichromatic Quantum Superpositions in Entangled Two-Photon Absorption Spectroscopy [0.0]
This work considers an alternative way of correlating photons by including energy superpositions. We study how the multichromatic quantum superposition, or color superposition of photon-pair states, influences the optical properties of organic chromophores.
arXiv Detail & Related papers (2023-03-01T15:16:39Z)
Quantum vortices of strongly interacting photons [52.131490211964014]
Vortices are hallmark of nontrivial dynamics in nonlinear physics. We report on the realization of quantum vortices resulting from a strong photon-photon interaction in a quantum nonlinear optical medium. For three photons, the formation of vortex lines and a central vortex ring attests to a genuine three-photon interaction.
arXiv Detail & Related papers (2023-02-12T18:11:04Z)
Quantum-limited millimeter wave to optical transduction [50.663540427505616]
Long distance transmission of quantum information is a central ingredient of distributed quantum information processors. Current approaches to transduction employ solid state links between electrical and optical domains. We demonstrate quantum-limited transduction of millimeter-wave (mmwave) photons into optical photons using cold $85$Rb atoms as the transducer.
arXiv Detail & Related papers (2022-07-20T18:04:26Z)
Quantum density matrix theory for a laser without adiabatic elimination of the population inversion: transition to lasing in the class-B limit [62.997667081978825]
No class-B quantum density-matrix model is available to date, capable of accurately describing coherence and photon correlations within a unified theory. Here we carry out a density-matrix theoretical approach for generic class-B lasers, and provide closed equations for the photonic and atomic reduced density matrix in the Fock basis of photons. This model enables the study of few-photon bifurcations and non-classical photon correlations in class-B laser devices, also leveraging quantum descriptions of coherently coupled nanolaser arrays.
arXiv Detail & Related papers (2022-05-26T16:33:51Z)
Optical manipulation of matter waves [0.0]
We show that matter waves can be optically manipulated via inelastic interactions with optical fields. Results support optical manipulation of matter waves as a powerful tool for microscopy, spectroscopy, and the exploration of novel fundamental phenomena associated with light-atom interactions.
arXiv Detail & Related papers (2022-03-14T16:39:54Z)
Self-Ordering of Individual Photons in Waveguide QED and Rydberg-Atom Arrays [0.548253258922555]
We study the propagation of light through an optical waveguide that is chirally coupled to three-level quantum emitters. We show that the additional laser-coupling to a third emitter state not only permits to control the properties of the bound state but can even eliminate it entirely. We demonstrate this emerging photon-photon repulsion by analysing the quantum dynamics of multiple photons in large emitter arrays.
arXiv Detail & Related papers (2021-10-25T13:55:10Z)
Topologically Protecting Squeezed Light on a Photonic Chip [58.71663911863411]
Integrated photonics offers an elegant way to increase the nonlinearity by confining light strictly inside the waveguide. We experimentally demonstrate the topologically protected nonlinear process of spontaneous four-wave mixing enabling the generation of squeezed light on a silica chip.
arXiv Detail & Related papers (2021-06-14T13:39:46Z)
An optical lattice with sound [0.0]
Quantised sound waves -- phonons -- govern the elastic response of crystalline materials. We create an optical lattice with phonon modes using a Bose-Einstein condensate (BEC) Our results pave the way for exploring the rich physics of elasticity in quantum solids.
arXiv Detail & Related papers (2021-04-28T17:59:27Z)

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