Your search keyword '"Optical lattices"' showing total 4,616 results

1. Realization of one-dimensional anyons with arbitrary statistical phase.

Author

Kwan, Joyce, Segura, Perrin, Li, Yanfei, Kim, Sooshin, Gorshkov, Alexey V., Eckardt, André, Bakkali-Hassani, Brice, and Greiner, Markus

Subjects

*ANYONS, *BOUND states, *OPTICAL lattices, *ENGINEERS, *FERMIONS, *BOSONS

Abstract

Low-dimensional quantum systems can host anyons, particles with exchange statistics that are neither bosonic nor fermionic. However, the physics of anyons in one dimension remains largely unexplored. In this work, we realize Abelian anyons in one dimension with arbitrary exchange statistics using ultracold atoms in an optical lattice, where we engineer the statistical phase through a density-dependent Peierls phase. We explore the dynamical behavior of two anyons undergoing quantum walks and observe the anyonic Hanbury Brown-Twiss effect as well as the formation of bound states without on-site interactions. Once interactions are introduced, we observe spatially asymmetric transport in contrast to the symmetric dynamics of bosons and fermions. Our work forms the foundation for exploring the many-body behavior of one-dimensional anyons. [ABSTRACT FROM AUTHOR]

Published

2024

2. Optimal Floquet state engineering for large scale atom interferometers.

Author

Rodzinka, T., Dionis, E., Calmels, L., Beldjoudi, S., Béguin, A., Guéry-Odelin, D., Allard, B., Sugny, D., and Gauguet, A.

Subjects

QUANTUM theory, ATOMIC beams, BEAM splitters, OPTICAL lattices, MOMENTUM transfer

Abstract

The effective control of atomic coherence with cold atoms has made atom interferometry an essential tool for quantum sensors and precision measurements. The performance of these interferometers is closely related to the operation of large wave packet separations. We present here a novel approach for atomic beam splitters based on the stroboscopic stabilization of quantum states in an accelerated optical lattice. The corresponding Floquet state is generated by optimal control protocols. In this way, we demonstrate an unprecedented Large Momentum Transfer (LMT) interferometer, with a momentum separation of 600 photon recoils (600 ℏk) between its two arms. Each LMT beam splitter is realized in a remarkably short time (2 ms) and is highly robust against the initial velocity dispersion of the wave packet and lattice depth fluctuations. Our study shows that Floquet engineering is a promising tool for exploring new frontiers in quantum physics at large scales, with applications in quantum sensing and testing fundamental physics. Large-scale atom interferometers enable precise measurements of fundamental constants and novel sensors. This study uses Floquet formalism to create an optimal transported state, resulting in an efficient large-momentum-transfer interferometer, advancing largescale interferometers. [ABSTRACT FROM AUTHOR]

Published

2024

3. Altermagnetic topological insulator with C-paired spin-valley locking.

Author

Ma, Hai-Yang and Jia, Jin-Feng

Subjects

*QUANTUM spin Hall effect, *TOPOLOGICAL insulators, *LATTICE theory, *DEGREES of freedom, *OPTICAL lattices

Abstract

Altermagnetism emerges as the third fundamental collinear magnetism recently. Associating nontrivial topology and quantum orders to this newly established magnetism is an important physical topic and may lead to interesting physics such as unusual quantum spin Hall effect with time-reversal-symmetry breaking, topological superconductivity and spin-valley locking. Here, we first generalize the spinless Haldane model from the usual honeycomb lattice to the otherwise simpler square lattice. We then restore the doublet spin degree of freedom, the resulted spinful model resembles the Kane-Mele model and is able to describe the unprecedented physics which intertwine C -paired spin-valley locking, Dirac physics, nontrivial band topology and altermagnetism. Our works shed lights on future studies and applications in spintronics and valleytronics for altermagnetic materials, the lattice theories developed in this article may also find their broad applications to optical lattice with ultra cold atoms, photonic lattice, etc. other than the usual electronic systems. [ABSTRACT FROM AUTHOR]

Published

2024

4. Quantum states and spectra of small cylindrical and toroidal lattices.

Author

Brooks, Caelan and Das, Kunal K

Subjects

*OPTICAL lattices, *QUANTUM states, *TOPOLOGICAL fields, *SPECTRAL lines, *INDUCTIVE effect

Abstract

We examine the spectrum and quantum states of small lattices with cylindrical and toroidal topology subject to a scalar gauge potential that introduces a position dependent phase in the inter-site coupling. Equivalency of gauges assumed in infinite lattices is generally lost due to the periodic boundary conditions, and conditions that restore it are identified. We trace the impact of various system parameters including gauge choice, boundary conditions and inter-site coupling strengths, and an additional axial field. We find gauge dependent appearance of avoided crossings and persistent degeneracies, and we show their impact on the associated eigenstates. Smaller lattices develop prominent gaps in spectral lines associated with edge states, which are suppressed in the thermodynamic limit. Toroidal lattices have counterparts of most of the features observed in cylindrical lattices, but notably they display a transition from localization to delocalization determined by the relation between the field parameter and the number of lattice sites. [ABSTRACT FROM AUTHOR]

Published

2024

5. Quantum phases of two-component bosons in a non-Hermitian optical lattice system.

Author

Zhang, Xiao-ru and Yang, Shi-Jie

Subjects

*OPTICAL lattices, *BOSONS, *PHASE separation, *TWO-dimensional models, *SUPERFLUIDITY, *ISLANDS

Abstract

In this paper, we investigate the quantum phases of two-component bosons in a non-Hermitian optical lattice system featuring a nonreciprocal hopping phase factor. Our analysis focuses on the Bose–Hubbard model in a two-dimensional (2D) square lattice, utilizing the inhomogeneous dynamical Gutzwiller mean-field theory (DGMFT) to examine the ground state. The impact on quantum phases of the inter component interaction varies in the weak-interaction (the inter-component interactions are smaller than intra-component interactions, i.e., | U a b | ≤ U) and in the strong-interaction (the inter-component interactions are bigger than intra-component interactions, i.e., U a b > U) regime. In the weak regime, we observe a diverse range of quantum phases, including vortex-like liquid, MI islands (the Mott insulator (MI) islands periodically distributed in the superfluid (SF) background) and SF islands (the SF islands periodically distributed in the MI background), and the inter-component counterflow superfluid (CFSF) phases. In the strong regime, we observe phase separation of the two-component bosons. [ABSTRACT FROM AUTHOR]

Published

2024

6. Analytical insights into cold bosonic atoms in a zigzag optical lattice: Invariant analysis, exact solutions, and bifurcation analysis using phase portraits.

Author

Yadav, Poonam and Kumar Gupta, Rajesh

Subjects

*OPTICAL lattices, *QUANTUM phase transitions, *NONLINEAR differential equations, *ELLIPTIC functions, *PERIODIC functions

Abstract

This work delves into the behavior of cold bosonic atoms within a zigzag optical lattice which offers a rich platform for studying quantum many‐body physics and has potential applications in various fields including quantum simulation, quantum computing, and precision measurement. The study aims to derive exact solutions and explore qualitative properties through dynamical analysis. Exact solutions of the nonlinear differential equation model can provide insights into the behavior of bosonic atoms in complex optical lattice configurations, allowing researchers to simulate and study phenomena such as quantum phase transitions, many‐body localization, and exotic states of matter. The invariant analysis has been performed for the first time on the specified equation, yielding a reduced system of equations with forms that are easier to handle. Novel techniques are applied to extract solutions from the reduced system of equations obtained via invariant analysis. The results reveal a rich set of solutions, including various traveling wave solutions and doubly periodic functions in the form of Jacobian elliptic functions. Bifurcation analysis, conducted through phase portraits, provides insights into the system's long‐term behavior under different parameter values. This work contributes to a deeper understanding of the dynamics of cold bosonic atoms in optical lattices via 2D and 3D plots of obtained solutions depicting the change in the behavior of soliton solutions with fractional derivative parameter. [ABSTRACT FROM AUTHOR]

Published

2024

7. Density–Density Correlation Spectra of Ultracold Bosonic Gas Released from a Deep 1D Optical Lattice.

Author

Tan, Yunzhi, Zhu, Qiang, Wang, Bing, Shi, Jingran, Xiong, Dezhi, and Lyu, Baolong

Subjects

*OPTICAL lattices, *QUANTUM tunneling, *STATISTICAL correlation, *GASES, *ATOMS, *GAS condensate reservoirs, *BOSE-Einstein condensation

Abstract

Density–density correlation analysis is a convenient diagnostic tool to reveal the hidden order in the strongly correlated phases of ultracold atoms. We report on a study of the density–density correlations of ultracold bosonic atoms which were initially prepared in a Mott insulator (MI) state in one-dimensional optical lattices. For the atomic gases released from the deep optical lattice, we extracted the normalized density–density correlation function from the atomic density distributions of freely expanded atomic clouds. Periodic bunching peaks were observed in the density–density correlation spectra, as in the case of higher-dimensional lattices. Treating the bosonic gas within each lattice well as a subcondensate without quantum tunneling, we simulated the post-expansion density distribution along the direction of the 1D lattice, and the calculated density–density correlation spectra agreed with our experimental observations. [ABSTRACT FROM AUTHOR]

Published

2024

8. Influence of the next-nearest neighbor and the boson–boson interactions on U-shaped, W-shaped profile and modulation instability gain spectra in a zig–zag optical lattice.

Author

Houwe, Alphonse, Abbagari, Souleymanou, Doka, Serge Yamigno, Inc, Mustafa, and Crepin, Kofane Timoleon

Subjects

*OPTICAL lattices, *OPTICAL solitons, *NONLINEAR Schrodinger equation, *MODULATIONAL instability, *ROGUE waves

Abstract

In this paper, we employ the auxiliary equation method (AEM) to show the leverage of the nearest neighbors hopping and the boson–boson interaction in a zig zag optical lattice on the stressed optical solitons (os) and the Modulation Instability (MI) gain of cold bosonic atoms. The pedestal of the work is set on the continuum approximation of a cold bosonic atoms in a zig zag optical lattice which has demonstrated in detailed in refs. [Tala-Tebue E, Rezazadeh H, Djoufack ZI, et al. Optical solutions of cold bosonic atoms in a zig–zag optical lattice. Opt Quant Electron 53(2021):44; Djoufack ZI, TalaTebue E, FotsaNgafo F, et al. Quantum breathers associated with modulational instability in 1D ultracold boson in optical lattices involving nextnearest neighbor interactions. Optik 164(2018):575–589]. The results collected have enclosed bright, dark optical solitons and the combined bright-dark and bright-bright optical solitons. Compared the acquired results with Tala-Tebue et al. [Optical solutions of cold bosonic atoms in a zig–zag optical lattice. Opt Quant Electron 53(2021):44], further the os including U-shaped and W-shaped profile have been drop in and the powerful of the nearest neighbors hopping and the boson–boson interaction has been exposed across the spatiotemporal and plot evolution of the bright and dark os. Therewith, the MI bands have been stressed and it is observed some new attitude of the MI gain spectra under the induction of the model parameters. The collected results are new in literature in our knowledge and will improve the previous results acquired in refs. [Tala-Tebue E, Rezazadeh H, Djoufack ZI, et al. Optical solutions of cold bosonic atoms in a zig–zag optical lattice. Opt Quant Electron 53(2021):44; Djoufack ZI, TalaTebue E, FotsaNgafo F, et al. Quantum breathers associated with modulational instability in 1D ultracold boson in optical lattices involving nextnearest neighbor interactions. Optik 164(2018):575–589; Zhao XH, Tian B, Liu DY, et al. Dark solitons interaction for a (2+1)-dimensional nonlinear Schrödinger equation in the Heisenberg ferromagnetic spin chain. Superlattices Microstruct 100(2016):587–595; Uddin MF, Hafez MG, Hammouch Z, et al. Periodic and rogue waves for Heisenberg models of ferromagnetic spin chains with fractional beta derivative evolution and obliqueness. Waves Random Complex Media 2020. https://doi.org/10.1080/17455030.2020.1722331; Inc M, Aliyu AI, Yusuf A. Optical solitons to the nonlinear Shrdingers equation with spatio-temporal dispersion using complex amplitude ansatz. J Mod Opt 2017;64(21):2273–2280]. [ABSTRACT FROM AUTHOR]

Published

2024

9. Quantum States of ultracold bosons in optical lattices interacting via long-range interaction.

Author

Panda, Rohit and Chatterjee, Budhaditya

Subjects

*OPTICAL lattices, *QUANTUM states, *NEIGHBORS

Abstract

We simulate a one-dimensional system of a few ultracold bosons trapped in an optical lattice with long-range interactions from an ab initio perspective using the MCTDH-B method. We emphasise the distinct influence of the long-range interactions and the effects not observed by systems with contact interactions. We consider both the nearest-neighbour and the next-nearest neighbour interactions in addition to the usual contact interactions. We observe and analyse the ground state that arises due to the intricate interplay between the interaction potentials and the non-trivial influence of the particle number. By systematically tuning the coupling between different interaction types and varying particle numbers across different regimes, we uncover a diverse set of novel ground-state configurations whose emergence is governed by the delicate interplay of competing energetic factors. [ABSTRACT FROM AUTHOR]

Published

2024

10. Existence and stability of discrete intersite bright solitons in Bose Einstein condensates in parabolic trapped optical lattices.

Author

Kumar, Ramesh, Singh, U., Swami, O. P., Suthar, G., and Nagar, A. K.

Subjects

*BOSE-Einstein condensation, *OPTICAL lattices, *MAGNETIC traps, *PERTURBATION theory, *NONLINEAR equations

Abstract

We consider intersite discrete bright solitons in one-dimensional Bose-Einstein condensate in parabolic trapped optical lattice. Analytical and numerical calculations are performed to determine the existence and stability of bright solitons. Analysis is based on continuous Gross-Pitaevskii equation and discrete nonlinear Schrodinger equation. It is observed that the strength of external magnetic trap can change the stability of bright solitons. Stability windows of bright solitons are presented and stability approximations are derived using perturbation theory, with their numerical results. [ABSTRACT FROM AUTHOR]

Published

2024

11. Dihedral beams.

Author

Jaimes-Nájera, Alfonso

Abstract

In this work, a group theory-based formulation that introduces new classes of dihedral-symmetric beams is presented. Our framework leverages the algebraic properties of the dihedral group of rotations and reflections to transform input beams into closed-form families of dihedral-invariant wavefields, which will be referred to as dihedral beams. Each transformation is associated with a specific dihedral group in such a way that each family of dihedral beams exhibits the symmetries of its corresponding group. Our approach is inspired by one of the outcomes of this work: elegant Hermite–Gauss beams can be described as a dihedral interference pattern of elegant traveling waves, a new set of solutions to the paraxial equation also developed in this paper. Particularly, when taking elegant traveling waves as input beams, they transform into elegant dihedral beams possessing quasi-crystalline properties and including features like phase singularities, self-healing, and pseudo-nondiffracting propagation, as well as containing elegant Hermite and Laguerre–Gauss beams as special cases. Our approach can be applied to arbitrary scalar and vector input beams and constitutes a general group-theory formulation that can be extended beyond the dihedral group. [ABSTRACT FROM AUTHOR]

Published

2025

12. Improving lattice-light-shift uncertainty of an 171Yb optical clock with optimized cooling and trapping lasers.

Author

Peng, Chengquan, Zhang, Tao, Sun, Changyue, Qi, Qichao, Jin, Taoyun, Lei, Shuai, Zhao, Chengcheng, Feng, Suzhen, Xia, Yan, and Xu, Xinye

Subjects

*ATOMIC clocks, *OPTICAL lattices, *FREQUENCY combs, *LASER cooling, *FREQUENCY stability, *OPTICAL frequency conversion

Abstract

Atoms confined in the optical lattice can be interrogated with Doppler- and recoil-free operation. However, if not properly controlled, the optical lattice may limit clock accuracy. To improve the lattice-light-shift uncertainty, the cooling and trapping lasers' frequency stability is optimized, and the atom's signal stability is enhanced. A ring-cavity Ti:sapphire laser is locked to the optical frequency comb, which is referenced to a 578 nm ultra-stable laser, and the beat note's stability is on the order of 10−16. Using a 10 cm Fabry–Pérot cavity referenced to the Ti:sapphire laser, the optical frequency stability is transferred to the 399 nm cooling laser, creating favorable conditions for evaluating the lattice-light-shift accurately. We reevaluate lattice-light-shift in our 171Yb optical lattice clock with an uncertainty of 8.1 × 10−18, which is an order lower than our previous result, and the magic frequency is determined to be 394 798 266.6(1.3) MHz. [ABSTRACT FROM AUTHOR]

Published

2024

13. Tetrahedra Modification of Phosphates for Optical Anisotropy Enhancement.

Author

Qiu, Haotian, An, Ran, Li, Junjie, Yang, Zhihua, Pan, Shilie, and Mutailipu, Miriding

Subjects

*CRYSTAL lattices, *BAND gaps, *OPTICAL lattices, *OPTICAL materials, *BIREFRINGENCE

Abstract

As an exceptional optical gene, the [PO4] tetrahedron is indispensable in the field of optical crystals due to its gain in the band gap of solid materials. However, the high symmetry of [PO4] tetrahedron hinders the achievement of large optical anisotropy in the lattice for phosphate crystal forms. In this work, the heteroleptic tetrahedra strategy, which involves replacing some of the oxygen atoms on regular oxy‐tetrahedra, is proven to be a feasible approach for preserving the wide transmission of the original [PO4] tetrahedra and improving the polarizability anisotropy. Based on this, eight methylphosphates are designed and synthesized for the phosphate system by substituting a [CH3] group for the O atom on the [PO4] tetrahedra. Theoretically, as compared to [PO4] units, [CH3PO3] and [CH3PO3H] units can improve the polarizability anisotropy, particularly [CH3PO3H] units, which have the potential to be birefringence‐active. The strong birefringence (exp. 0.108@546.1 nm) and short deep‐UV cutoff edge (195 nm) of nonmetallic methylphosphates [C(NH2)3][CH3PO3H] in the series suggest that it may be a possible short‐wave UV birefringent crystal. In addition to providing new birefringence‐active units for optical material design, this study validates the viability of modifying tetrahedra to improve inherent short board of nearly rigid [PO4] tetrahedra in phosphate family. [ABSTRACT FROM AUTHOR]

Published

2024

14. Symmetry‐Determined Lasing from Incommensurate Moiré Nanoparticle Lattices.

Author

Fasanelli, Fabio M., Freire‐Fernández, Francisco, and Odom, Teri W.

Subjects

*NANOPARTICLES, *COHERENCE (Optics), *ROTATIONAL symmetry, *LIGHT sources, *OPTICAL lattices, *ELECTRON beams

Abstract

This paper describes how moiré plasmonic nanoparticle lattices can exhibit lasing action over a broad wavelength and wavevector range. Moiré nanolithography is combined with the PEEL (Photolithography, Etching, Electron‐beam deposition, and Lift‐off) process to fabricate in‐plane incommensurate lattices with optical properties beyond the restricted geometries of Bravais lattices. Because of increased rotational symmetry, moiré lattices support a larger number of transverse electric and transverse magnetic modes relative to their periodic base lattices. It is found that multidirectional lasing characteristics can be predicted by the symmetry of the moiré reciprocal lattice. Incommensurate moiré plasmonic lattices combine advantages of the dense band structures observed in aperiodic lattices with that of predicted modes in Bravais lattices for light‐based technologies in coherent light sources and multiplexed data transfer. [ABSTRACT FROM AUTHOR]

Published

2024

15. An efficient method to generate near-ideal hollow beams of different shapes for box potential of quantum gases.

Author

Ren, Tongtong, Wang, Yirong, Dai, Xiaoyu, Gao, Xiaoxu, Sun, Guangren, Zhao, Xue, Gao, Kuiyi, Zheng, Zhiyue, and Zhang, Wei

Subjects

*QUANTUM gases, *QUANTUM theory, *GAUSSIAN beams, *DIGITAL technology, *MICROMIRROR devices, *OPTICAL lattices

Abstract

Ultracold quantum gases are usually prepared in conservative traps for quantum simulation experiments. The atomic density inhomogeneity, together with the consequent position-dependent energy and time scales of cold atoms in traditional harmonic traps, makes it difficult to manipulate and detect the sample at a higher level. These problems are partially solved by optical box traps made of blue-detuned hollow beams. However, generating a high-quality hollow beam with high light efficiency for the box trap is challenging. Here, we present a scheme that combines the fixed optics, including axicons and prisms, to pre-shape a Gaussian beam into a hollow beam with a digital micromirror device (DMD) to improve the quality of the hollow beam further, providing a nearly ideal optical potential of various shapes for preparing highly homogeneous cold atoms. The highest power-law exponent of potential walls can reach a value over 100, and the light efficiency from a Gaussian to a hollow beam is also improved compared to direct optical shaping by a mask or a DMD. Combined with a one-dimensional optical lattice, a nearly ideal two-dimensional uniform quantum gas with different geometrical boundaries can be prepared for exploring quantum many-body physics to an unprecedented level. [ABSTRACT FROM AUTHOR]

Published

2024

16. Perfect Off-Axis Optical Vortex Lattice.

Author

Tai, Yuping, Qin, Xueyun, Li, Chenying, Wei, Wenjun, Zhang, Hao, and Li, Xinzhong

Subjects

PHYSICAL optics, OPTICAL measurements, ANGULAR momentum (Mechanics), OPTICAL lattices, AMPLITUDE modulation, OPTICAL communications

Abstract

Optical vortex lattices (OVLs) with diverse modes show potential for a wide range of applications, such as high-capacity optical communications, optical tweezers, and optical measurements. However, vortices in typical regulated OVLs often exhibit irregular shapes, such as being narrow and elongated. The resulting increase in asymmetry negatively impacts the efficiency of particle trapping. Additionally, the vortex radii expand with an increase in topological charge (TC), limiting the TC value of the vortices and hindering their ability to fully utilize orbital angular momentum (OAM). Herein, we propose an alternative approach to custom OVLs using off-axis techniques combined with amplitude modulation. Amplitude modulation enables the precise generation of an OVL with perfect vortex properties, known as a perfect off-axis OVL. Further, the number of vortices in the perfect off-axis OVL, the off-axis distances, and the TC can be freely modulated while maintaining a circular mode. This unique OVL will promote new applications, such as the complex manipulation of multi-particle systems and optical communication based on OAM. [ABSTRACT FROM AUTHOR]

Published

2024

17. Achievement splitting for topological states with pseudospin in phase modulation by using gyromagnetic photonic crystals.

Author

He, Liu, Yang, Yuting, Ren, Qun, Wang, Xiuyu, Wu, Liang, and Yao, Jianquan

Subjects

*PHASE modulation, *PHOTONIC crystals, *ELECTRICAL conductors, *CIRCULAR polarization, *SIGNAL processing, *OPTICAL lattices, *SPIRAL antennas

Abstract

As we know, valley-Hall kink states or pseudospin helical edge states are excited by polarized-momentum-locking [left-handed circular polarization (LCP) and right-handed circular polarization (RCP)] because the valley-Hall kink modes or pseudospin polarized modes have intrinsic and local chirality, which is difficult for these states to achieve phase modulation. Here we theoretically design and study a compatible topological photonic system with coexistence of photonic quantum Hall phase and pseudospin Hall phase, which is composed of gyromagnetic photonic crystals with a deformed honeycomb lattice containing six cylinders. A typical kind of hybrid topological waveguide states with pseudospin-characteristic, magnetic field-dependent, and strong robustness against backscattering and perfect electric conductor (PEC) is realized in the present system. Furthermore, we re-design a structure with intersection-liked, achieve splitting for one-way pseudospin quantum Hall edge states by using phase modulation. Robustness of the one-way pseudospin-quantum Hall edge states in splitting has been demonstrated as well. Additionally, PEC inserted in transport channel brings optical path difference in waveguide transmission, which would influence splitting for hybrid topological waveguide states in phase difference modulation. This work not only provides a new way for manipulation (i.e., phase modulation) of hybrid topological waveguide states in compatible topological photonic system from distinct topological classes but also has potential in various applications, such as sensing, signal processing, and on-chip communications. [ABSTRACT FROM AUTHOR]

Published

2024

18. Anisotropic optical response of Nb2SiTe4 under pressure.

Author

Qiao, Liangxin, Hu, Chuansheng, Lu, Tenglong, Zhang, Jiluan, Xie, Shiyu, Liu, Hengjie, Liu, Miao, and Qi, Zeming

Subjects

*ANISOTROPIC crystals, *RAMAN spectroscopy, *INFRARED spectroscopy, *ELECTRONIC structure, *OPTICAL lattices

Abstract

The optical response of a layered anisotropic crystal Nb2SiTe4 was investigated under varying pressure using synchrotron infrared spectroscopy, Raman spectroscopy, and first-principles calculation. This study revealed diverse trends in optical response and bandgap at different pressure levels. Below 5 GPa, the bandgap decreases rapidly due to the reduction of interlayer distance. The Raman and infrared optical response show significant changes at 11 and 21 GPa, suggesting structural and electronic structure transformation at these pressure points. Meanwhile, the optical responses exhibited distinct pressure effects along different crystal axes. Overall, these results provide valuable insights into the pressure-induced lattice deformation and optical transitions in Nb2SiTe4 and similar layered anisotropic materials, contributing to an insightful understanding of layered materials under pressure. [ABSTRACT FROM AUTHOR]

Published

2024

19. Introduction to theoretical and experimental aspects of quantum optimal control.

Author

Ansel, Q, Dionis, E, Arrouas, F, Peaudecerf, B, Guérin, S, Guéry-Odelin, D, and Sugny, D

Subjects

*BOSE-Einstein condensation, *HAMILTONIAN mechanics, *LAGRANGIAN mechanics, *OPTICAL lattices, *ELECTROMAGNETIC fields

Abstract

Quantum optimal control (QOC) is a set of methods for designing time-varying electromagnetic fields to perform operations in quantum technologies. This tutorial paper introduces the basic elements of this theory based on the Pontryagin maximum principle, in a physicist-friendly way. An analogy with classical Lagrangian and Hamiltonian mechanics is proposed to present the main results used in this field. Emphasis is placed on the different numerical algorithms to solve a QOC problem. Several examples ranging from the control of two-level quantum systems to that of Bose–Einstein condensates (BECs) in a one-dimensional optical lattice are studied in detail, using both analytical and numerical methods. Codes based on shooting method and gradient-based algorithms are provided. The connection between optimal processes and the quantum speed limit is also discussed in two-level quantum systems. In the case of BEC, the experimental implementation of optimal control protocols is described, both for two-level and many-level cases, with the current constraints and limitations of such platforms. This presentation is illustrated by the corresponding experimental results. [ABSTRACT FROM AUTHOR]

Published

2024

20. Non-Hermitian propagation in equally-spaced waveguide arrays.

Author

Bocanegra-Garay, Ivan A and Moya-Cessa, Héctor M

Subjects

*OPTICAL waveguides, *ANALYTICAL solutions, *OPTICAL lattices

Abstract

A non-unitary transformation leading to a Hatano–Nelson problem is performed on an array of equally-spaced optical waveguides. Such transformation produces a non-reciprocal system of waveguides, as the corresponding Hamiltonian becomes non-Hermitian. This may be achieved by judiciously choosing an attenuation (amplification) of the injected (or exciting) field. The non-Hermitian transport induced by such transformation is studied for several cases and closed analytical solutions, not present in the available literature, are straightforwardly obtained. The corresponding non-Hermitian Hamiltonian may represent an open system that interacts with the environment, either loosing to or being provided with energy from the exterior. [ABSTRACT FROM AUTHOR]

Published

2024

21. A quantum-network register assembled with optical tweezers in an optical cavity.

Author

Hartung, Lukas, Seubert, Matthias, Welte, Stephan, Distante, Emanuele, and Rempe, Gerhard

Subjects

*OPTICAL resonators, *QUANTUM logic, *QUANTUM computing, *QUANTUM networks (Optics), *PHOTON emission, *OPTICAL lattices, *OPTICAL tweezers

Abstract

Quantum computation and quantum communication are expected to provide users with capabilities inaccessible by classical physics. However, scalability to larger systems with many qubits is challenging. One solution is to develop a quantum network consisting of small-scale quantum registers containing computation qubits that are reversibly interfaced to communication qubits. In this study, we report on a register that uses both optical tweezers and optical lattices to deterministically assemble a two-dimensional array of atoms in an optical cavity. Harnessing a single atom-addressing beam, we stimulate the emission of a photon from each atom and demonstrate multiplexed atom-photon entanglement with a generation-to detection efficiency approaching 90%. Combined with cavity-mediated quantum logic, our approach provides a possible route to distributed quantum information processing. [ABSTRACT FROM AUTHOR]

Published

2024

22. Spin–orbit-coupled Bose gas with Rydberg interactions confined in a two-dimensional optical lattice.

Author

Wang, Lin-Xue, Kong, Fang, Yang, Hong-Li, Zhai, Hao-Han, Liu, Hui, Yang, Xue-Ying, and Zhang, Xiao-Fei

Subjects

*BOSE-Einstein gas, *OPTICAL lattices, *SPIN-orbit interactions, *UNIT cell, *CELL size, *CELL anatomy

Abstract

We consider the ground state of Rydberg-dressed Bose gas with spin–orbit coupling and confined in a two-dimensional optical lattice. The effects of system's parameters, especially the nonlocal Rydberg interaction and spin–orbit coupling, on the ground-state structure of such a system are explored in full parameter space. It is found that in the absence of spin–orbit coupling, the ground-state structure of the system changes from the initial optical lattice structure to a two-dimensional periodic one with the cell size decreasing with the strength of Rydberg interaction. In the presence of spin–orbit coupling, both the phase and the internal structure of unit cell show strong dependence on the strength of spin–orbit coupling. Finally, the strong interacting gas is also considered. [ABSTRACT FROM AUTHOR]

Published

2024

23. Generation of chiral optical vortex lattice for controlled aggregation of particles.

Author

Yang, X. B., Zhang, H., Tang, M. M., Ma, H. X., Tai, Y. P., and Li, X. Z.

Subjects

*OPTICAL lattices, *OPTICAL vortices, *OPTICAL tweezers, *PARTICLE motion, *PARTICLE tracks (Nuclear physics), *VECTOR beams

Abstract

The chiral light field has attracted great attention owing to its interaction with chiral matter. The generation of chiral light fields with rich structures has become crucial as it can expand application scenarios. Herein, we introduce a chiral optical vortex lattice. As a whole, the optical vortex lattice has a chiral intensity distribution, with each spiral arm having sub-vortices (chiral phase). By using an expansion factor to adjust the involute of a circular lattice, this helical optical vortex lattice can be continuously varied from a circular lattice. The chirality of intensity and phase can be controlled independently. Furthermore, the optical tweezers using the lattice demonstrate the capability of sub-vortices to manipulate particle movement, with the chiral intensity determining the trajectory of particle motion. As the lattice possesses both intensity and phase chirality, it may also find potential applications in tasks such as chiral structure microfabrication. [ABSTRACT FROM AUTHOR]

Published

2024

24. Controlling many-body quantum chaos: Bose–Hubbard systems.

Author

Beringer, Lukas, Steinhuber, Mathias, Diego Urbina, Juan, Richter, Klaus, and Tomsovic, Steven

Subjects

*QUANTUM chaos, *CHAOS theory, *OPTICAL lattices, *QUANTUM states, *CHEMICAL potential

Abstract

This work develops a quantum control application of many-body quantum chaos for ultracold bosonic gases trapped in optical lattices. It is long known how to harness exponential sensitivity to changes in initial conditions for control purposes in classically chaotic systems. In the technique known as targeting, instead of a hindrance to control, the instability becomes a resource. Recently, this classical targeting has been generalized to quantum systems either by periodically countering the inevitable quantum state spreading or by introducing a control Hamiltonian, where both enable localized states to be guided along special chaotic trajectories toward any of a broad variety of desired target states. Only strictly unitary dynamics are involved; i.e. it gives a coherent quantum targeting. In this paper, the introduction of a control Hamiltonian is applied to Bose–Hubbard systems in chaotic dynamical regimes. Properly selected unstable mean field solutions can be followed particularly rapidly to states possessing precise phase relationships and occupancies. In essence, the method generates a quantum simulation technique that can access rather special states. The protocol reduces to a time-dependent control of the chemical potentials, opening up the possibility for application in optical lattice experiments. Explicit applications to custom state preparation and stabilization of quantum many-body scars are presented in one- and two-dimensional lattices (three-dimensional applications are similarly possible). [ABSTRACT FROM AUTHOR]

Published

2024

25. Energy spectrum and superfluidity breakdown of Bose–Einstein condensates in optical lattice under density-dependent artificial gauge field.

Author

Zhou, Ming-Zhi, Ma, Yun-E, Xu, Shi-Dong, Mi, Lai-Lai, Zhang, Ai-Xia, and Xue, Ju-Kui

Subjects

*OPTICAL lattices, *BOSE-Einstein condensation, *SUPERFLUIDITY, *MOMENTUM transfer, *ATOMIC interactions, *PHASE diagrams, *GAUGE field theory

Abstract

Nonlinear feedback between the gauge field and the material field can yield novel quantum phenomena. Here, the interplay between a density-dependent artificial gauge field and Bose–Einstein condensates (BECs) trapped in an optical lattice is studied. The energy spectrum and superfluidity represented by energetic and dynamical stabilities of the system are systematically discussed. A density-dependent artificial gauge field with a back-action between the BECs dynamics and the gauge field induces an effective atomic interaction that depends on the quasi-momentum and density of the condensates, resulting in a symmetry-broken energy spectrum and exotic stability phase diagram, that is, the system is only stable in a certain range of atoms density and under a limited lattice strength. The density-dependent artificial gauge field changes the sequence for the emergence of energetic and dynamical instability and the regimes of the energetic and dynamical instabilities are significantly separated, offering an efficient way to examine the energetic and dynamical instabilities of superfluids separately. In particular, the density-dependent artificial gauge field, as a mechanism for transferring momentum to the fluid, results in dynamic instability of the condensates even in free space. Our results provide deep insights into the dynamical response of superfluid systems to gauge fields and have potential applications for the coherent control of exotic superfluid states. [ABSTRACT FROM AUTHOR]

Published

2024

26. Dirac Cones and Room Temperature Polariton Lasing Evidenced in an Organic Honeycomb Lattice.

Author

Betzold, Simon, Düreth, Johannes, Dusel, Marco, Emmerling, Monika, Bieganowska, Antonina, Ohmer, Jürgen, Fischer, Utz, Höfling, Sven, and Klembt, Sebastian

Subjects

*OPTICAL lattices, *ORGANIC semiconductors, *HONEYCOMB structures, *EPITAXY, *OPTICS, *EXCITON theory, *POLARITONS

Abstract

Artificial 1D and 2D lattices have emerged as a powerful platform for the emulation of lattice Hamiltonians, the fundamental study of collective many‐body effects, and phenomena arising from non‐trivial topology. Exciton‐polaritons, bosonic part‐light and part‐matter quasiparticles, combine pronounced nonlinearities with the possibility of on‐chip implementation. In this context, organic semiconductors embedded in microcavities have proven to be versatile candidates to study nonlinear many‐body physics and bosonic condensation, and in contrast to most inorganic systems, they allow the use at ambient conditions since they host ultra‐stable Frenkel excitons. A well‐controlled, high‐quality optical lattice is implemented that accommodates light‐matter quasiparticles. The realized polariton graphene presents with excellent cavity quality factors, showing distinct signatures of Dirac cone and flatband dispersions as well as polariton lasing at room temperature. This is realized by filling coupled dielectric microcavities with the fluorescent protein mCherry. The emergence of a coherent polariton condensate at ambient conditions are demonstrated, taking advantage of coupling conditions as precise and controllable as in state‐of‐the‐art inorganic semiconductor‐based systems, without the limitations of e.g. lattice matching in epitaxial growth. This progress allows straightforward extension to more complex systems, such as the study of topological phenomena in 2D lattices including topological lasers and non‐Hermitian optics. [ABSTRACT FROM AUTHOR]

Published

2024

27. Scattering of Bright Solitons Due to Defects in Binary Bose‐Einstein Condensates with Nonlinear Optical Lattices.

Author

Sekh, Golam Ali

Subjects

*OPTICAL lattices, *BOSE-Einstein condensation, *SOLITONS

Abstract

Spatially overlapped coupled matter‐wave bright solitons are considered in binary Bose‐Einstein condensates with nonlinear optical lattices(NOLs) and study the properties of scattering patterns due to a localized defect. It is shown that spatially overlapped solitons become separated and exhibit different scattering patterns with the variation of inter‐species interaction. The NOL interplays with the defect and tends to influence the scattering properties. However, the effect of NOL varies with strength of inter‐component interaction. It is found that, if this interaction is weak then the scattering center gets shifted outside the defect. However, for a stronger inter‐component interaction, the scattering takes place from the defect and leads to different scattering patterns. [ABSTRACT FROM AUTHOR]

Published

2024

28. Dynamics of the partially coherent radially polarized rotating elliptical cosine-Gaussian optical lattice through anisotropic turbulence.

Author

Zhang, Liping, Deng, Dongmei, He, Shangling, Peng, Xi, Yang, Xiangbo, and Wang, Guanghui

Subjects

*OPTICAL lattices, *TURBULENCE, *LATTICE constants, *LIGHT intensity

Abstract

Based on the extended Huygens–Fresnel integral, the analytical expressions for the average intensity of a partially coherent radially polarized rotating elliptical cosine-Gaussian optical lattice (PCRPREGOL) in the anisotropic turbulence are derived. We find that the lattice intensity profile and the spatial degree of coherence will display periodicity reciprocity over a long propagation distance even though the lattices are affected by the turbulence. The periodicity reciprocity of PCRPREGOL is not only affected by the lattice parameter but also affected by the beam order factor. The intensity pattern of the PCRPREGOL in a certain distance can be modulated by the lattice lobes, and some interesting phenomena appear due to the overlap of four lattice arrays during the evolution of the PCRPREGOL. At the same time, the four periodic grid patterns and the tapered light intensity composed by four parts of the PCRPREGOL can be flexibly tuned by modulating the source correlation parameters and the lattice constant. Last but not least, we also discuss the coherent and polarized characteristics of the PCRPREGOL in the anisotropic turbulence. [ABSTRACT FROM AUTHOR]

Published

2024

29. A Cellular Automaton Approach for Efficient Computing on Surface Chemical Reaction Networks.

Author

Yu, Sihai, Xu, Wenli, Lee, Jia, and Isokawa, Teijiro

Subjects

*SURFACE reactions, *CELLULAR automata, *CHEMICAL reactions, *ASYNCHRONOUS circuits, *OPTICAL lattices, *CONFERENCES & conventions

Abstract

A surface chemical reaction network (sCRN, Qian and Winfree in DNA Computing and Molecular Programming: 20th International Conference, DNA 20, Kyoto, Japan, September 22–26, 2014. Proceedings 20. Springer, 2014) is an emergent paradigm for molecular programming, in which a chemical molecule is placed at each site of a lattice, and each molecule may undergo either bi-molecular reactions associated with one of the nearest molecules or uni-molecular reactions autonomously. The lattice structure as well as the localized reactions between molecules facilitate an effective formalization of sCRNs in the framework of cellular automata. This formalism not only allows a systematic evaluation of the complexity of a sCRN, but also enables a formal approach to reduce the model's complexity for the sake of improving its effectiveness. To this end, this paper proposes a new sCRN model that has less complexity measured in terms of the numbers of both cell states and transition rules. Especially, universality of computations will be shown by implementing all asynchronous circuits, including the well-known full-adder, into the sCRN. The decreased complexity may enhance the feasibility of the proposed sCRN model for physical implementation. [ABSTRACT FROM AUTHOR]

Published

2024

30. Superlattice Symmetries Reveal Electronic Topological Transition in CaC 6 with Pressure.

Author

Wang, Bruce, Bianconi, Antonio, Mackinnon, Ian D. R., and Alarco, Jose A.

Subjects

SUPERCONDUCTING transition temperature, SUPERCONDUCTORS, FERMI surfaces, ELECTRONIC band structure, OPTICAL lattices, SUPERLATTICES, BRILLOUIN zones

Abstract

The electronic properties of calcium-intercalated graphite (CaC6) as a function of pressure are revisited using density functional theory (DFT). The electronic band structures of CaC6, like many other layered superconducting materials, display cosine-shaped bands at or near the Fermi level (FL). Such bands encompass bonding/antibonding information with a strong connection to superconducting properties. Using a hexagonal cell representation for CaC6, the construction of a double supercell in the c-direction effects six-folding in the reciprocal space of the full cosine function, explicitly revealing the bonding/antibonding relationship divide at the cosine midpoint. Similarly, folding of the Fermi surface (FS) reveals physical phenomena relevant to electronic topological transitions (ETTs) with the application of pressure. The ETT is characterised by a transition of open FS loops to closed loops as a function of pressure. As the highest transition temperature is reached with pressure, the dominant continuous, open FS loops shift to a different region of the FS. For CaC6, the peak value for the superconducting transition temperature, Tc, occurs at about 7.5 GPa, near the observed pressure of the calculated ETT. At this pressure, the radius of the nearly spherical Ca 4s-orbital FS coincides with three times the distance from the Γ centre point to the Brillouin zone (BZ) boundary of the 2c supercell. In addition, the ETT coincides with the alignment of the nonbonding (inflection) point of the cosine band with the FL. At other calculated pressure conditions, the Ca 4s-orbital FS undergoes topological changes that correspond and can be correlated with experimentally determined changes in Tc. The ETT is a key mechanism that circumscribes the known significant drop in Tc for CaC6 as a function of increasing pressure. Consistent calculated responses of the ETT to pressure match experimental measurements and validate the examination of superlattices as important criteria for understanding mechanisms driving superconductivity. [ABSTRACT FROM AUTHOR]

Published

2024

31. Synchronous Comparison of Two Thulium Optical Clocks.

Author

Golovizin, A., Mishin, D., Provorchenko, D., Tregubov, D., and Kolachevsky, N.

Subjects

*ATOMIC clocks, *MEASUREMENT errors, *OPTICAL lattices, *THULIUM

Abstract

The experimental comparison of two thulium optical lattice clocks in a time interval of up to one hour has been carried out. The synchronous comparison of a clock transition in two independent atomic ensembles using a single ultrastable laser has allowed us to eliminate fluctuations of the laser frequency from the measured frequency difference and to reach a relative measurement error of 10–16 after 500-s averaging, which corresponds to a relative instability of . The successful demonstration of the long-term operation of two systems using the synchronous comparison of clock transitions opens the possibility of studying systematic shifts in thulium optical clocks with an uncertainty of 10–17. [ABSTRACT FROM AUTHOR]

Published

2024

32. Suppressing electron disorder-induced heating of ultracold neutral plasma via optical lattice.

Author

Wang, Haibo, Yao, Zonglin, Huang, Haoyu, Sun, Jianing, Zhou, Fuyang, Wu, Yong, Wang, Jianguo, and Chen, Xiangjun

Subjects

*OPTICAL lattices, *MOLECULAR dynamics, *HEATING, *ELECTRON plasma, *ELECTRONS, *COULOMB barriers (Nuclear fusion)

Abstract

Disorder-induced heating (DIH) prevents ultracold neutral plasma into the electron strong coupling regime. Here, we propose a scheme to suppress electronic DIH via optical lattice. We simulate the evolution dynamics of ultracold neutral plasma constrained by three-dimensional optical lattice using the classical molecular dynamics method. The results show that for experimentally achievable conditions, electronic DIH is suppressed by a factor of 1.3, and the Coulomb coupling strength can reach 0.8, which is approaching the strong coupling regime. Suppressing electronic DIH via optical lattice may pave a way for the research of electronic strongly coupled plasma. [ABSTRACT FROM AUTHOR]

Published

2024

33. Polarization-controlled unidirectional lattice plasmon modes via a multipolar plasmonic metasurface.

Author

Mousavi, Seyedehniousha, Butt, Muhammad Abdullah, Jafari, Zeinab, Reshef, Orad, Boyd, Robert W., Banzer, Peter, and De Leon, Israel

Subjects

*PLASMONICS, *DIFFRACTION gratings, *OPTICAL control, *DEGREES of freedom, *OPTICAL properties, *OPTICAL lattices, *OPTICAL polarization

Abstract

Diffractive plasmonic metasurfaces offer the possibility of controlling the flow of light in flat optical systems through the excitation of lattice plasmon modes by a careful metasurface design. Nonetheless, a remaining challenge for this type of structure is the dynamic control of its optical properties via degrees of freedom, such as the polarization states of incoming light. In this report, we explain theoretically and demonstrate experimentally the polarization control over amplitude and propagation direction of lattice plasmon modes supported by a multipolar plasmonic metasurface. These unidirectional optical waves result from the coupling between near-field effects of individual meta-atoms and far-field effects originating from the lattice modes. The device operates over a broad wavelength range, maintaining its directional behavior and enabling it to operate also as a polarization-controlled directional diffraction grating, a power splitter, or an optical router for on-chip photonics applications. [ABSTRACT FROM AUTHOR]

Published

2024

34. Control of Spectral Extreme Events in Ultrafast Fiber Lasers by a Genetic Algorithm.

Author

Wu, Xiuqi, Zhang, Ying, Peng, Junsong, Boscolo, Sonia, Finot, Christophe, and Zeng, Heping

Subjects

*GENETIC algorithms, *ROGUE waves, *BOSE-Einstein condensation, *FIBER lasers, *OPTICAL spectra, *RADIANT intensity, *OPTICAL lattices

Abstract

Extreme wave events or rogue waves (RWs) are both statistically rare and of exceptionally large amplitude. They are observed in many complex systems ranging from oceanic and optical environments to financial models and Bose–Einstein condensates. As they appear from nowhere and disappear without a trace, their emergence is unpredictable and non‐repetitive, which makes them particularly challenging to control. Here, the use of genetic algorithms (GAs), which are exclusively designed for searching and optimizing stationary or repetitive processes in nonlinear optical systems, is extended to the active control of extreme events in a fiber laser cavity. Feeding real‐time spectral measurements into a GA controlling the electronics to optimize the cavity parameters, the wave events are able to be triggered in the cavity that have the typical statistics of RWs in the frequency domain. The intensity of the induced RWs can also be tailored. This accurate control enables the generation of optical RWs with a spectral peak intensity 32.8 times higher than the significant intensity threshold. A rationale is proposed and confirmed by numerical simulations of the laser model for the related frequency up‐ and downshifting of the optical spectrum that are experimentally observed. [ABSTRACT FROM AUTHOR]

Published

2024

35. Collapse Dynamics of Vector Vortex Beams in Kerr Medium with Parity–Time-Symmetric Lattice Modulation.

Author

Zan, Xiaoxu, Yao, Gang, Wu, Yan, Guan, Ying, Chew, Khian-Hooi, and Chen, Rui-Pin

Subjects

VECTOR beams, NONLINEAR Schrodinger equation, OPTICAL lattices, OPACITY (Optics), OPTICAL vortices, GEOMETRIC shapes

Abstract

Based on the two-dimensional (2D) nonlinear Schrödinger equation, we investigate the collapse dynamics of a vector vortex optical field (VVOF) in nonlinear Kerr media with parity–time (PT)-symmetric modulation. The critical power for the collapse of a VVOF in a Kerr-ROLP medium (Kerr medium with a real optical lattice potential) is derived. Numerical simulations indicate that the number, position, propagation distance, and collapse profile of the collapse of a VVOF in sine and cosine parity–time-symmetric potential (SCPT) Kerr media are closely related to the modulation depth, initial powers, and the topological charge number of a VVOF. The VVOF collapses into symmetric shapes during propagation in a Kerr-ROLP medium, and collapse shapes are sensitively related to the density of the PT-symmetric optical lattice potential. In addition, due to gain–loss, the VVOF will be distorted during propagation in the Kerr-SCPT medium, forming an asymmetric shape of collapse. The power evolution of the VVOF in a Kerr-SCPT medium as a function of the transmission distance with different modulating parameters and topological numbers is analyzed in detail. The introduction of PT-symmetric optical lattice potentials into nonlinear Kerr materials may provide a new approach to manipulate the collapse of the VVOF. [ABSTRACT FROM AUTHOR]

Published

2024

36. Mott insulator to superfluid with staggered phase in driven optical lattices.

Author

Shettigar, Sheshgiri S., Alavani, Bhargav K., and Pai, Ramesh V.

Subjects

*OPTICAL lattices, *METAL-insulator transitions, *SUPERFLUIDITY, *FIRST-order phase transitions, *QUANTUM phase transitions, *DENSITY matrices, *HUBBARD model

Abstract

Motivated by the recent realization of the strongly correlated driven many-body system showing tunable continuous to the discontinuous quantum phase transition betweenMott insulator (MI) and superfluid with staggered phase (π-SF), we study the two-band extended Bose Hubbard model using the density matrix renormalization group with mean-field (CMFT+DMRG) method in one spatial dimension. In this model, the inter-band coupling and effective detuning energy are related to the resonant shaking frequency and amplitude. We calculate the superfluid order parameters and density of bosons in lower and upper bands to identify the underlining MI and π-SF phases. The bosons transfer from the lower band (ground state) to the upper band (first excited state) when the resonant shaking frequency is increased. For small shaking amplitude, the transfer of bosons is sudden giving rise to discontinuous MI to π-SF transition. For the case of large shaking amplitudes. the boson transferscontinuouslyreflect a continuous MI to π-SF transition. We compare our results with the earlier work. [ABSTRACT FROM AUTHOR]

Published

2024

37. Path integral molecular dynamics for thermodynamics and Green's function of ultracold spinor bosons.

Author

Yu, Yongle, Liu, Shujuan, Xiong, Hongwei, and Xiong, Yunuo

Subjects

*PATH integrals, *THERMODYNAMICS, *BOSONS, *MOMENTUM distributions, *OPTICAL lattices, *GREEN'S functions, *MOLECULAR dynamics, *MOMENTUM transfer

Abstract

Most recently, the path integral molecular dynamics has been successfully used to consider the thermodynamics of single-component identical bosons and fermions. In this work, the path integral molecular dynamics is developed to simulate thermodynamics, Green's function, and momentum distribution of two-component bosons in three dimensions. As an example of our general method, we consider the thermodynamics of up to 16 bosons in a three-dimensional harmonic trap. For noninteracting spinor bosons, our simulation shows a bump in the heat capacity. As the repulsive interaction strength increases, however, we find the gradual disappearance of the bump in the heat capacity. We believe that this simulation result can be tested by ultracold spinor bosons with optical lattices and magnetic-field Feshbach resonance to tune the inter-particle interaction. We also calculate Green's function and momentum distribution of spinor bosons. Our work facilitates the exact numerical simulation of spinor bosons, whose property is one of the major problems in ultracold Bose gases. [ABSTRACT FROM AUTHOR]

Published

2022

38. Ultrafast vibrational excitation transfer on resonant antenna lattices revealed by two-dimensional infrared spectroscopy.

Author

Cohn, Bar, Sufrin, Shmuel, and Chuntonov, Lev

Subjects

*INFRARED spectroscopy, *METHYL methacrylate, *MOLECULAR vibration, *ANTENNA arrays, *OPTICAL devices, *OPTICAL lattices

Abstract

High-quality lattice resonances in arrays of infrared antennas operating in an open-cavity regime form polariton states by means of strong coupling to molecular vibrations. We studied polaritons formed by carbonyl stretching modes of (poly)methyl methacrylate on resonant antenna arrays using femtosecond 2DIR spectroscopy. At a normal incidence of excitation light, doubly degenerate antenna-lattice resonances (ALRs) form two polariton states: a lower polariton and an upper polariton. At an off-normal incidence geometry of 2DIR experiments, the ALR degeneracy is lifted and, consequently, the polariton energies are split. We spectrally resolved and tracked the time-dependent evolution of a cross-peak signal associated with the excitation of reservoir states and the unidirectional transfer of the excess energy to lower polaritons. Bi-exponential decay of the cross-peak suggests that a reversible energy exchange between the bright and dark lower polaritons occurs with a characteristic transfer time of ∼200 fs. The cross-peak signal further decays within ∼800 fs, which is consistent with the relaxation time of the carbonyl stretching vibration and with the dephasing time of the ALR. An increase in the excitation pulse intensity leads to saturation of the cross-peak amplitude and a modification of the relaxation dynamics. Using quantum-mechanical modeling, we found that the kinetic scheme that captures all the experimental observations implies that only the bright lower polariton accepts the energy from the reservoir, suggesting that transfer occurs via a mechanism involving dipole–dipole interaction. An efficient reservoir-to-polariton transfer can play an important role in developing novel room-temperature quantum optical devices in the mid-infrared wavelength region. [ABSTRACT FROM AUTHOR]

Published

2022

39. Comprehensive quantum transport analysis of M-superlattice structures for barrier infrared detectors.

Author

Singh, Anuja, Mukherjee, Swarnadip, and Muralidharan, Bhaskaran

Subjects

*INFRARED detectors, *STRUCTURAL engineering, *GREEN'S functions, *OPTICAL lattices, *LIBRARY materials, *STRUCTURAL engineers, *SUPERLATTICES

Abstract

In pursuit of designing superior type-II superlattice barrier infrared detectors, this study encompasses an exhaustive analysis of utilizing M-structured superlattices for both the absorber and barrier layers through proper band engineering and discusses its potential benefits over other candidates. The electronic band properties of ideally infinite M-structures are calculated using the eight band k. p method that takes into account the effects of both strain and microscopic interface asymmetry to primarily estimate the bandgap and density-of-states effective mass and their variation with respect to the thicknesses of the constituent material layers. In contrast, for practical finite-period structures, the local density-of-states and spectral tunneling transmission and current calculated using the Keldysh non-equilibrium Green's function approach with the inclusion of non-coherent scattering processes offer deep insights into the qualitative aspects of miniband and localization engineering via structural variation. Our key results demonstrate how to achieve a wide infrared spectral range, reduce tunneling dark currents, induce strong interband wavefunction overlaps at the interfaces for adequate absorption, and excellent band-tunability to facilitate unipolar or bipolar current blocking barriers. This study, therefore, perfectly exemplifies the utilization of 6.1 Å material library to its full potential through the demonstration of band engineering in M-structured superlattices and sets up the right platform to possibly replace other complex superlattice systems for targeted applications. [ABSTRACT FROM AUTHOR]

Published

2022

40. An interface trap charge model for simulation of graphene-based synaptic field effect transistors.

Author

Oshio, Reon and Souma, Satofumi

Subjects

*FIELD-effect transistors, *SUPERLATTICES, *NEUROPLASTICITY, *SIMULATION methods & models, *ORGANIC field-effect transistors, *OPTICAL lattices

Abstract

We propose a compact computational method based on the capacitance model for the efficient design of graphene-based synaptic field effect transistors (FETs), in which the hysteresis of conduction characteristics due to the channel–gate interface trap is used as synaptic plasticity. Using our method to calculate the conduction properties of graphene and armchair graphene nanoribbon (AGNR) superlattice FETs, it is shown that the AGNR can achieve an efficient conductance change rate Δ w , which is approximately 7.4 times that of graphene. It was also found that Δ w was the greatest when the gate oxide thickness was around 2–3 nm, which is near the limit of miniaturization. These results suggest that the proposed synaptic FETs are a promising approach to realize large scale integration chips for biological timescale computation. [ABSTRACT FROM AUTHOR]

Published

2022

41. Selection and enhancement of the frequency modes with Floquet exceptional points and chiral Zener tunneling.

Author

Chen, Yuelan, Zhang, Penghao, Hong, Chao, Song, Yiling, Ke, Shaolin, Wang, Mingfeng, Liu, Weiwei, and Lu, Peixiang

Subjects

*TUNNEL design & construction, *SIGNAL processing, *NUMERICAL analysis, *DYNAMICAL systems, *OPTOELECTRONICS, *OPTICAL communications, *OPTICAL lattices

Abstract

Mode selecting plays a vital role in the field of optoelectronics, such as optical communication, signal processing, on-chip light manipulation, mode conversion, and frequency synthesis. In this work, flexible selection and enhancement of the frequency modes in an unidirectional coupled Su–Schrieffer–Heeger (SSH) frequency lattice are obtained with Floquet exceptional points (EPs) and chiral Zener tunneling (ZT). The unidirectional coupled non-Hermitian SSH frequency lattices are synthesized by a double-ring system with complex dynamical modulations. Under an effective direct current (dc) force induced by the phase-mismatching of the modulations, the two Floquet bands of the non-Hermitian frequency lattices are degenerated and the Floquet EPs arise. Therefore, the unidirectional and irreversible frequency mode conversion takes place, which is the chiral ZT. Moreover, through perturbation analysis and numerical simulations, we prove that the frequency modes of the two-band system can be selected and enhanced by a multi-photon resonance dc force. [ABSTRACT FROM AUTHOR]

Published

2024

42. Vortices in multilayer stacks of Bose–Einstein condensates with tilted dipoles.

Author

Zhao, Qiang

Subjects

*BOSE-Einstein condensation, *DIPOLE-dipole interactions, *GROSS-Pitaevskii equations, *ANGULAR momentum (Mechanics), *STATISTICAL correlation, *OPTICAL lattices, *ROTATIONAL motion

Abstract

In this paper, we consider the formation of vortices in multilayer stacks of Bose–Einstein condensates with tilted dipoles by numerical simulations of the Gross–Pitaevskii equation. Different dependencies of critical rotation frequency (CRF) and optical lattice height, vortex number, and rotation frequency are studied, depending on the direction of the dipole axis and dipole strength. Our results show that the CRF in z = 0 is minimum. When the optical lattice height is gradually increased, the CRF decreases gradually. Reducing of dipole strength in anisotropic dipole–dipole interaction (DDI) favours the formation of vortices, and such decline in isotropic DDI hinders the creation of vortices. The reason for this difference is that the repulsive interaction is favorable and the attractive interaction is disadvantageous for the vortex formation. In addition, we study the first-order correlation function and focus on variation of coherence. For small rotation frequency, the break of coherence occurs earlier in the case of purely repulsive interaction. With an increase in rotation frequency, the coherence concurrently disappears in layer z = 2. Moreover, we also investigate the quenched dynamics, showing that the increase of angular momentum is induced by changing the direction of dipoles and in this process the vortex number remains unchanged. [ABSTRACT FROM AUTHOR]

Published

2024

43. Island myriads in periodic potentials.

Author

Lazarotto, Matheus J., Caldas, Iberê L., and Elskens, Yves

Subjects

*OPTICAL lattices, *ROTATIONAL symmetry, *ORBITS (Astronomy), *SURFACE potential, *POTENTIAL functions, *PHASE space, *ARCHIPELAGOES

Abstract

A phenomenon of emergence of stability islands in phase space is reported for two periodic potentials with tiling symmetries, one square and the other hexagonal, inspired by bidimensional Hamiltonian models of optical lattices. The structures found, here termed as island myriads, resemble web-tori with notable fractality and arise at energy levels reaching that of unstable equilibria. In general, the myriad is an arrangement of concentric island chains with properties relying on the translational and rotational symmetries of the potential functions. In the square system, orbits within the myriad come in isochronous pairs and can have different periodic closure, either returning to their initial position or jumping to identical sites in neighbor cells of the lattice, therefore impacting transport properties. As seen when compared to a more generic case, i.e., the rectangular lattice, the breaking of square symmetry disrupts the myriad even for small deviations from its equilateral configuration. For the hexagonal case, the myriad was found but in attenuated form, mostly due to extra instabilities in the potential surface that prevent the stabilization of orbits forming the chains. [ABSTRACT FROM AUTHOR]

Published

2024

44. Periodic dynamics of optical skyrmion lattices driven by symmetry.

Author

Zhang, Qiang, Yang, Aiping, Xie, Zhenwei, Shi, Peng, Du, Luping, and Yuan, Xiaocong

Subjects

*OPTICAL vortices, *OPTICAL lattices, *MOMENTUM space, *OPTICAL engineering, *QUANTUM gases, *SYMMETRY, *SKYRMIONS, *QUANTUM states

Abstract

The recently developed concept of optical skyrmions has introduced an exciting dimension to the emerging field of Poincaré engineering in optical lattices. There remains an unexplored territory in investigating system geometries to enhance the versatility of manipulating the topological landscape within optical lattices. Here, we present both experimental and theoretical evidence showcasing the periodic vectorial characteristics of field- and spin-based skyrmion lattices, generated by plasmonic vortices with varying topological charges. Our findings reveal that the geometric symmetry of the system plays a pivotal role in governing the periodic arrangement of these vortex patterns. Building upon this arrangement, the orbital–orbital coupling of plasmonic vortices gives rise to densely packed energy flow distributions, intricately bonded to topological charges. Consequently, this results in the formation of sublattices within the momentum space, each characterized by distinct k-vectors. Skyrmion and meron topologies, driven by the intrinsic spin–orbital coupling, are presented in these lattices. This proposed framework illuminates how symmetry serves as a fundamental tool in the manipulation of optical lattice topologies, opening up new avenues in fields ranging from optical trapping, laser writing, quantum gas microscopy, to electron quantum state control, each of which is poised to benefit from these nontrivial advances. [ABSTRACT FROM AUTHOR]

Published

2024

45. Noise Differentiation and Atom Number Measurement in Optical Lattice Clocks by Analyzing Clock Stabilities with Various Parameters.

Author

Zhao, Guodong, Guo, Feng, Lu, Xiaotong, and Chang, Hong

Subjects

ATOMIC clocks, OPTICAL measurements, OPTICAL lattices, QUANTUM noise, ATOMS, NOISE

Abstract

We propose a method that enables the precise determination of the number of atoms in a Dick-noise-free optical lattice clock, by effectively addressing quantum projection noise. Our approach relies on conducting stability measurements at three distinct parameter sets, allowing us to differentiate between quantum projection noise, photon shot noise, and technical noise. Importantly, it enables accurate extraction of the atom number, even in the presence of photon shot noise and technical noise. We utilize numerical simulations to validate our approach, optimize the modulation parameters for minimal uncertainty, and investigate the impact of atom number fluctuations on the determinacy of our results. The numerical results show the validity of our method and demonstrate an estimated uncertainty in the atom number that is below 4% with 6.7 h measurement, provided that the standard deviation of atom number fluctuation is kept below 0.14 times the average atom number. [ABSTRACT FROM AUTHOR]

Published

2024

46. Rotation sensing using tractor atom interferometry.

Author

Dash, Bineet, Goerz, Michael H., Duspayev, Alisher, Carrasco, Sebastián C., Malinovsky, Vladimir S., and Raithel, Georg

Subjects

INTERFEROMETRY, OPTICAL lattices, TRACTORS, ATOMS, ROTATIONAL motion, SIMULATION methods & models

Abstract

We investigate the possible realization of an ultracold-atom rotation sensor that is based on recently proposed tractor atom interferometry (TAI). An experimental design that includes the generation of a Laguerre–Gaussian-beam-based "pinwheel" optical lattice and multi-loop interferometric cycles is discussed. Numerical simulations of the proposed system demonstrate TAI rotation sensitivity comparable to that of contemporary matter-wave interferometers. We analyze a regime of TAI rotation sensors in which nonadiabatic effects may hinder the system's performance. We apply quantum optimal control to devise a methodology suitable to address this nonadiabaticity. Our studies are of interest for current efforts to realize compact and robust matter-wave rotation sensors, as well as for fundamental physics applications of TAI. [ABSTRACT FROM AUTHOR]

Published

2024

47. 2D Exotic Optical Lattice via a Digital‐Coding Circular Airy Beam.

Author

Sun, Peisheng, Chen, Lai, Pan, Bailiang, Ye, Linhua, Wang, Chengfeng, Zhang, Junxiang, and Wang, Li-Gang

Subjects

LIGHT propagation, OPTICAL devices, OPTICAL lattices, QUANTUM theory, KALEIDOSCOPES

Abstract

Optical lattices have been widely used from classical to quantum physics. The tunable and scalable fabrication of lattices would be of great significance in lattice‐based multipartite applications. This work demonstrates first that a circular Airy beam (CAB), which has the peculiar properties of self‐healing and abrupt autofocusing, can be used to generate two‐dimensional (2D) optical lattices in propagation when encoded by a programmable spatial mask, resulting in the formation of large‐scale and tunable optical lattices with both axis and axial symmetry, and even high‐orbital kaleidoscope shapes. The efficient diffraction of CAB during the spatial crosstalk with the mask enables the realization of tunable lattices with rich periodicity and complexity. The study shows a flexible method to manipulate lattices with large‐scale and versatile structures for potential applications in integrated and scalable optical and photonic devices. [ABSTRACT FROM AUTHOR]

Published

2024

48. Prospective Optical Lattice Clocks in Neutral Atoms with Hyperfine Structure.

Author

Bothwell, Tobias

Subjects

ATOMIC clocks, OPTICAL lattices, HYPERFINE structure, RIESZ spaces, FREQUENCY standards, EXCITED states

Abstract

Optical lattice clocks combine the accuracy and stability required for next-generation frequency standards. At the heart of these clocks are carefully engineered optical lattices tuned to a wavelength where the differential AC Stark shift between ground and excited states vanishes—the so called 'magic' wavelength. To date, only alkaline-earth-like atoms utilizing clock transitions with total electronic angular momentum J = 0 have successfully realized these magic wavelength optical lattices at the level necessary for state-of-the-art clock operation. In this article, we discuss two additional types of clock transitions utilizing states with J ≠ 0 , leveraging hyperfine structure to satisfy the necessary requirements for controlling lattice-induced light shifts. We propose realizing (i) clock transitions between same-parity clock states with total angular momentum F = 0 and (ii) M1/E2 clock transitions between a state with F = 0 and a second state with J = 1 / 2 , m F = 0 . We present atomic species which fulfill these requirements before giving a detailed discussion of both manganese and copper, demonstrating how these transitions provide the necessary suppression of fine structure-induced vector and tensor lattice light shifts for clock operations. Such realization of alternative optical lattice clocks promises to provide a rich variety of new atomic species for neutral atom clock operation, with applications from many-body physics to searches for new physics. [ABSTRACT FROM AUTHOR]

Published

2024

49. Gravity measurement at the sub-millimeter scale with optical lattice clock.

Author

Xiao, Sheng-Xian, Liang, Ying, Zhang, Ya, and Wang, Tao

Subjects

*ATOMIC clocks, *OPTICAL lattices, *QUANTUM noise, *QUANTUM measurement, *SCALING (Social sciences), *GRAVIMETRY, *RABI oscillations

Abstract

Due to the excellent accuracy, the optical lattice clock (OLC) has not only achieved impressive results in frequency measurement but also gradually plays an important role in quantum precision measurement. In this paper, we propose a scheme for measuring gravity at the sub-millimeter scale extracted from the Rabi spectrum based on Super-Bloch oscillations of atoms in the OLC. Our proposal can be realized on the existing OLC platform without significant change. Under realistic existing experimental parameters of 87 S r OLC, we determine the optimal experimental conditions and obtain a sensitivity of 5 μ Gal / Hz in the quantum projection noise limit, which is 50 times better than the previous method at the sub-millimeter scale under the same consideration. Another advantage of our proposal is that it is insensitive to the noise of the lattice laser, which contributes to the major uncertainty of the previous measurement (PRA 86, 033615). Our research will promote the development of OLC geoscopy. [ABSTRACT FROM AUTHOR]

Published

2024

50. Vortices number and the critical atoms number of a rotating Bose–Einstein condensates in two-dimensional optical lattice.

Author

Hassan, Ahmed S., Soliman, Shemi S. M., and Mahmoud, Alyaa A.

Subjects

*OPTICAL lattices, *BOSE-Einstein condensation, *BOSE-Einstein gas, *THERMODYNAMIC potentials, *ATOMS

Abstract

In this paper, the vortices number and the critical atoms number are calculated. Calculations are performed for ultracold trapped Bose gas in two-dimensional deep optical lattice. Hellmann–Feynman theorem is used here to calculate the expectation values of the angular momentum and thermal average of square radius (in situ size). The above-mentioned parameters are calculated from the thermodynamic grand potential q (α , s). The latter is calculated using a conventional semi-classical approximation. This thermodynamic grand potential allows us to investigate the impacts of the finite size and inter-atomic interaction effects. The obtained result for the vortices number has a peak with increase in the rate of rotation. While the critical atoms number has increase in nature with increase in the critical temperature. These parameters show a major dependence on the inter-atomic interaction, depth of optical lattice and number of particles. [ABSTRACT FROM AUTHOR]

Published

2024