October 2024
·
7 Reads
Physical Review A
This page lists works of an author who doesn't have a ResearchGate profile or hasn't added the works to their profile yet. It is automatically generated from public (personal) data to further our legitimate goal of comprehensive and accurate scientific recordkeeping. If you are this author and want this page removed, please let us know.
October 2024
·
7 Reads
Physical Review A
May 2023
·
12 Reads
·
3 Citations
Over the last two decades, the hierarchical equations of motion (HEOM) of Tanimura and Kubo have become the equation of motion-based tool for numerically exact calculations of system-bath problems. The HEOM is today generalized to many cases of dissipation and transfer processes through an external bath. In spatially extended photonic systems, the propagation of photons through the bath leads to retardation/delays in the coupling of quantum emitters. Here, the idea behind the HEOM derivation is generalized to the case of photon retardation and applied to the simple example of two dielectric slabs. The derived equations provide a simple reliable framework for describing retardation and may provide an alternative to path-integral treatments.
January 2023
·
42 Reads
Over the last two decades, the hierarchical equations of motion (HEOM) of Tanimura and Kubo have become the equation of motion-based tool for numerically exact calculations of system-bath problems. The HEOM is today generalized to many cases of dissipation and transfer processes through an external bath. In spatially extended photonic systems, the propagation of photons through the bath leads to retardation/delays in the coupling of quantum emitters. Here, the idea behind the HEOM derivation is generalized to the case of photon retardation and applied to the simple example of two dielectric slabs. The derived equations provide a simple reliable framework for describing retardation and may provide an alternative to path integral treatments.
November 2022
·
18 Reads
·
5 Citations
Nonlinear optical effects such as four-wave mixing and generation of squeezed light are ubiquitous in optical devices and light sources. For new devices operating at low optical power, the resonant nonlinearity arising from the two-photon sensitive bound biexciton in a semiconductor microcavity is an interesting prospective platform. Due to the particularly strong Coulomb interaction in atomically thin semiconductors, these materials have strongly bound biexcitons and operate in the visible frequency range of the electromagnetic spectrum. To remove the strong pump laser from the generated light in optical devices or to simultaneously excite nondegenerate polaritons, a bichromatic-pump configuration with two spectrally separated pump lasers is desirable. In this paper, we theoretically investigate spontaneous four-wave mixing and quadrature-squeezing in a bichromatically pumped atomically thin semiconductor microcavity. We explore two different configurations that support degenerate and nondegenerate scattering from polaritons into bound biexcitons, respectively. We find that these configurations lead to the generation of strongly single- and two-mode quadrature-squeezed light.
August 2022
·
19 Reads
·
8 Citations
Physical Review Letters
Modification of electromagnetic quantum fluctuations in the form of quadrature squeezing is a central quantum resource, which can be generated from nonlinear optical processes. Such a process is facilitated by coherent two-photon excitation of the strongly bound biexciton in atomically thin semiconductors. We show theoretically that interfacing an atomically thin semiconductor with an optical cavity makes it possible to harness this two-photon resonance and use the biexcitonic parametric gain to generate squeezed light with input power an order of magnitude below current state-of-the-art devices with conventional third-order nonlinear materials that rely on far off-resonant nonlinearities. Furthermore, the squeezing bandwidth is found to be in the range of several meV. These results identify atomically thin semiconductors as a promising candidate for on-chip squeezed-light sources.
July 2022
·
11 Reads
Nonlinear optical effects such as four-wave mixing and generation of squeezed light are ubiquitous in optical devices and light sources. For new devices operating at low optical power, the resonant nonlinearity arising from the two-photon sensitive bound biexciton in a semiconductor microcavity is an interesting prospective platform. Due to the particularly strong Coulomb interaction in atomically thin semiconductors, these materials have strongly bound biexcitons and operate in the visible frequency range of the electromagnetic spectrum. To remove the strong pump laser from the generated light in optical devices or to simultaneously excite non-degenerate polaritons, a bichromatic-pump configuration with two spectrally separated pump lasers is desirable. In this paper, we theoretically investigate spontanous four-wave mixing and quadrature-squeezing in a bichromatically pumped atomically thin semiconductor microcavity. We explore two different configurations that support degenerate and non-degenerate scattering from polaritons into bound biexcitons, respectively. We find that these configurations lead to the generation strongly single- and two-mode quadrature-squeezed light.
April 2022
·
13 Reads
·
22 Citations
Physical Review Letters
Multitime system correlation functions are relevant in various areas of physics and science, dealing with system-bath interaction including spectroscopy and quantum optics, where many of these schemes include an off-diagonal system bath interaction. Here we extend the enhanced time-evolving matrix product operator (eTEMPO) algorithm for quantum path integrals using tensor networks [Phys. Rev. Lett. 123, 240602 (2019)PRLTAO0031-900710.1103/PhysRevLett.123.240602 to open quantum systems with off-diagonal coupling beyond a single two level system. We exemplify the approach on a coupled cavity waveguide system with spatially separated quantum two-state emitters, though many other applications in material science are possible, including entangled photon propagation, photosynthesis spectroscopy, and on-chip quantum optics with realistic dissipation.
March 2022
·
12 Reads
Modification of electromagnetic quantum fluctuations in the form of quadrature-squeezing is a central quantum resource, which can be generated from nonlinear optical processes. Such a process is facilitated by coherent two-photon excitation of the strongly bound biexciton in atomically thin semiconductors. We show theoretically that interfacing an atomically thin semiconductor with an optical cavity allows to harness this two-photon resonance and use the biexcitonic parametric gain to generate squeezed light with input power an order of magnitude below current state-of-the-art devices with conventional third-order nonlinear materials that rely on far off-resonant nonlinearities. Furthermore, the squeezing bandwidth is found to be in the range of several meV. These results identify atomically thin semiconductors as a promising candidate for on-chip squeezed-light sources.
October 2021
·
6 Reads
Multitime system correlations functions are relevant in various areas of physics and science, dealing with system-bath interaction including spectroscopy and quantum optics, where many of these schemes include an off-diagonal system bath interaction. Here we extend the enhanced TEMPO algorithm for quantum path integrals using tensor networks [Phys. Rev. Lett. 123, 240602 (2019)] to open quantum systems with off-diagonal coupling beyond a single two level system. We exemplify the approach on a coupled cavity waveguide system with spatially separated quantum two-state emitters, though many other applications in material science are possible, including entangled photon propagation, photosynthesis spectroscopy and on-chip quantum optics with realistic dissipation.
June 2021
·
121 Reads
·
41 Citations
Physical Review Letters
We demonstrate a fundamental breakdown of the photonic spontaneous emission (SE) formula derived from Fermi’s golden rule, in absorptive and amplifying media, where one assumes the SE rate scales with the local photon density of states, an approach often used in more complex, semiclassical nanophotonics simulations. Using a rigorous quantization of the macroscopic Maxwell equations in the presence of arbitrary linear media, we derive a corrected Fermi’s golden rule and master equation for a quantum two-level system (TLS) that yields a quantum pumping term and a modified decay rate that is net positive. We show rigorous numerical results of the temporal dynamics of the TLS for an example of two coupled microdisk resonators, forming a gain-loss medium, and demonstrate the clear failure of the commonly adopted formulas based solely on the local density of states.
... The HEOM approach has been successfully applied to various interacting systems, such as molecular junctions [56], quantum dots [57], photosynthetic complexes [58,59], and cavity QED settings [39,60,61]. These systems involve different types of environments, such as electronic leads, phonon baths, or electromagnetic fields. ...
May 2023
... Later, Yan et al. experimentally observed double symmetrical EIT windows instead of multiple absorption peaks in hot atomic vapors [36]. In recent years, four-wave mixing (FWM) signals in such systems has attracted great interest [37][38][39]. For example, multi-channel FWM process [40], phase compensation induced by anomalous dispersion [41], and high-efficiency reflection [42]. ...
November 2022
... In 2022, Jiang et al. proposed a scheme to prepare ideal orthogonal squeezed states in one-dimensional harmonic systems using feedback control measurements on non-commuting observable quantities [57]. Recently, Denning et al. theoretically proved that proved that combining an atomically thin semiconductors and optical microcavities makes it possible to generate squeezed light with an input power one order of magnitude lower than traditional third-order nonlinear materials used to generate squeezed light [58]. In above calculations, we suppose that all the photon detectors are ideal on-demand detectors with the detection efficiency of 100%. ...
August 2022
Physical Review Letters
... Owing to their practicality and efficiency, PT-MPOs have seen wide adoption within a few years of their inception [24,25]. For example, Denning et al. [9], Fux et al. [26], and Vannucci and Gregersen [27] have used PT-MPOs to study the dynamics of semiconductor quantum dots interacting with a phonon bath, while Richter and Hughes have described two emitters coupled to a common waveguide [28]. We recently demonstrated a divide-and-conquer algorithm for constructing periodic , which has enabled million-time-step simulations, e.g., for modelling experiments measuring quantum dot emission spectra after timedependent (pulsed) driving by Boos et al. [30] as well as the analysis of two-color excitation with strongly off-resonant laser pulses by Bracht et al. [31]. ...
April 2022
Physical Review Letters
... To describe the quantum features in these interactions, a rigorous quantization scheme incorporating the three modes in inhomogeneous absorptive medium is needed. A macroscopic QED method based on the dyadic Green's tensor has been developed via describing the metal absorption to the EMF by a quantum noise, which guarantees the canonical commutation relations of the quantized field [45][46][47][48][49][50][51][52]. The quantized electric field readŝ ...
June 2021
Physical Review Letters
... For example, in [23], the density-matrix formalism of two-level quantum systems is combined with QNM theory to predict that the near-field response of a quantum emitter coupled to surface plasmons exhibits Fano line shapes that vary with the spatial coordinate. Similar conclusions have been reached in related theoretical studies on emitter-plasmon systems using slightly different approaches [24][25]. Furthermore, it has been demonstrated that the Purcell-effect spectrum of emitters coupled to spectrally overlapping resonances can also exhibit Fano line shapes [26], a phenomenon well understood within the framework of non-Hermitian complex mode volumes [27]. ...
September 2020
Physical Review Research
... The transverse free space photonic Green function G is well known [27], and we employ its far-field form later. Note that even considering free space with a dielectric function ǫ(r, ω) = 1, the fields are expressed in terms of a (fictitious) imaginary part of the dielectric function; formally, one can consider a dielectric function with an imaginary component which vanishes upon taking a limit after all spatial integrals involving the permittivity have been evaluated [28]. No physical predictions depend on this fictitious imaginary component of the permittivity. ...
August 2020
Physical Review Research
... The second is calculating the figures of merit Q/V, Purcell factor and local optical density of states (LDOS) of the hybrid cavities [37][38][39][40][41][42]. The third is simulating the interaction of light and matter and cavity quantum electrodynamics (cavity-QED) properties of the hybrid system [43][44][45][46][47][48][49][50][51][52][53][54][55][56][57][58]. The last is topological PhC-plasmonic hybrid devices [59,60]. ...
May 2020
... This neural network realization of the density matrix certainly is a great achievement, however, as of yet its potential has not been fully unleashed. In order to expand the representational power of the RBM beyond pure spin-1/2 systems, in the following we present a highly efficient and scalable mapping of Fock number states to the artificial neurons by subjecting the bosonic Fock state basis to a bit encoding scheme [35,36]: ...
February 2020
... Some of the plasmon-based applications such as plasmonic sensors, nanolasers, and single-photon sources [10,13,14] benefit from a narrow spectral linewidth and prolonged lifetime of plasmonic modes. Consequently, narrowing plasmon resonance linewidth and extending its lifetime have been the subject of extensive research [15][16][17], where the interplay between plasmon linewidth Γ and dephasing time T 2 is determined from the relationship T 2 = 2ℏ/Γ. ...
July 2019
ACS Photonics