Semiclassical dynamics in the presence of loss and gain Eva-Maria Graefe Department of Mathematics, Imperial College London, UK Non-Hermitian Photonics.

Slides:

Advertisements

Similar presentations

Wigner approach to a two-band electron-hole semi-classical model n. 1 di 22 Graz June 2006 Wigner approach to a two-band electron-hole semi-classical model.

Advertisements

The Schrödinger Wave Equation 2006 Quantum MechanicsProf. Y. F. Chen The Schrödinger Wave Equation.

Quantum Harmonic Oscillator

Chapter 1 Electromagnetic Fields

Wavepacket1 Reading: QM Course packet FREE PARTICLE GAUSSIAN WAVEPACKET.

Bloch Oscillations Alan Wu April 14, 2009 Physics 138.

Wave functions of different widths were used and then the results were analyzed next to each other. As is evident from the graphs below, the wider the.

Symmetry. Phase Continuity Phase density is conserved by Liouville’s theorem.  Distribution function D  Points as ensemble members Consider as a fluid.

The Klein Gordon equation (1926) Scalar field (J=0) :

A Bloch Band Base Level Set Method in the Semi-classical Limit of the Schrödinger Equation Hailiang Liu 1 and Zhongming Wang 2 Abstract It is now known.

Lecture I: The Time-dependent Schrodinger Equation  A. Mathematical and Physical Introduction  B. Four methods of solution 1. Separation of variables.

Instanton representation of Plebanski gravity Eyo Eyo Ita III Physics Department, US Naval Academy Spanish Relativity Meeting September 10, 2010.

GENERAL PRINCIPLES OF BRANE KINEMATICS AND DYNAMICS Introduction Strings, branes, geometric principle, background independence Brane space M (brane kinematics)

Chang-Kui Duan, Institute of Modern Physics, CUPT 1 Harmonic oscillator and coherent states Reading materials: 1.Chapter 7 of Shankar’s PQM.

Christopher Devulder, Slava V. Rotkin 1 Christopher Devulder, Slava V. Rotkin 1 1 Department of Physics, Lehigh University, Bethlehem, PA INTRODUCTION.

Simulating Electron Dynamics in 1D

Semi-classics for non- integrable systems Lecture 8 of “Introduction to Quantum Chaos”

1 Waves 8 Lecture 8 Fourier Analysis. D Aims: ëFourier Theory: > Description of waveforms in terms of a superposition of harmonic waves. > Fourier series.

1 Introduction to quantum mechanics (Chap.2) Quantum theory for semiconductors (Chap. 3) Allowed and forbidden energy bands (Chap. 3.1) What Is An Energy.

Ch 9 pages Lecture 22 – Harmonic oscillator.

Petra Zdanska, IOCB June 2004 – Feb 2006 Resonances and background scattering in gedanken experiment with varying projectile flux.

Quantization via Fractional Revivals Quantum Optics II Cozumel, December, 2004 Carlos Stroud, University of Rochester Collaborators:

Vlasov Equation for Chiral Phase Transition

A class of localized solutions of the linear and nonlinear wave equations D. A. Georgieva, L. M. Kovachev Fourth Conference AMITaNS June , 2012,

Engineering the Dynamics Engineering Entanglement and Correlation Dynamics in Spin Chains Correlation Dynamics in Spin Chains [1] T. S. Cubitt 1,2 and.

Advanced methods of molecular dynamics 1.Monte Carlo methods 2.Free energy calculations 3.Ab initio molecular dynamics 4.Quantum molecular dynamics III.

VARENNA 2007 Introduction to 5D-Optics for Space-Time Sensors Introduction to 5D-Optics for Space-Time Sensors Christian J. Bordé A synthesis between optical.

To Address These Questions, We Will Study:

The quantum kicked rotator First approach to “Quantum Chaos”: take a system that is classically chaotic and quantize it.

Transport in potentials random in space and time: From Anderson localization to super-ballistic motion Yevgeny Krivolapov, Michael Wilkinson, SF Liad Levy,

Monday, March 30, 2015PHYS , Spring 2015 Dr. Jaehoon Yu 1 PHYS 3313 – Section 001 Lecture #15 Monday, March 30, 2015 Dr. Jaehoon Yu Wave Motion.

TIME REFRACTION and THE QUANTUM PROPERTIES OF VACUUM J. T. Mendonça CFP and CFIF, Instituto Superior Técnico Collaborators R. Bingham (RAL), G. Brodin.

E. Todesco, Milano Bicocca January-February 2016 Appendix A: A digression on mathematical methods in beam optics Ezio Todesco European Organization for.

WIR SCHAFFEN WISSEN – HEUTE FÜR MORGEN Pendulum Equations and Low Gain Regime Sven Reiche :: SwissFEL Beam Dynamics Group :: Paul Scherrer Institute CERN.

Review for Exam 2 The Schrodinger Eqn.

Einstein’s coefficients represent a phenomenological description of the matter-radiation interaction Prescription for computing the values of the A and.

Quantum Reflection off 2D Corrugated Surfaces

One Dimensional Quantum Mechanics: The Free Particle

Quantum Mechanics for Applied Physics

Chapter 1 Electromagnetic Fields

UNIT 1 Quantum Mechanics.

The Landau-Teller model revisited

Christopher Crawford PHY 520 Introduction Christopher Crawford

THE METHOD OF LINES ANALYSIS OF ASYMMETRIC OPTICAL WAVEGUIDES Ary Syahriar.

Review Lecture Jeffrey Eldred Classical Mechanics and Electromagnetism

Atomic BEC in microtraps: Heisenberg microscopy of Zitterbewegung

4. The Postulates of Quantum Mechanics 4A. Revisiting Representations

Wigner approach to a new two-band

Christopher Crawford PHY 520 Introduction Christopher Crawford

Elements of Quantum Mechanics

1 Thursday Week 2 Lecture Jeff Eldred Review

Coherent Nonlinear Optics

Fourier transforms and

Quantum mechanics II Winter 2012

Quantum mechanics II Winter 2011

Quantum Spacetime and Cosmic Inflation

Operators Postulates W. Udo Schröder, 2004.

Summary of Lecture 18 导波条件图解法求波导模式边界条件波导中模式耦合的微扰理论

SIMONS FOUNDATION 160 Fifth Avenue New York, NY 10010

Gaussian Wavepacket in an Infinite square well

Quantum mechanics I Fall 2012

Classical Mechanics Pusan National University

Department of Electronics

Linear Vector Space and Matrix Mechanics

PHYS 3313 – Section 001 Lecture #17

Spreading of wave packets in one dimensional disordered chains

Haris Skokos Max Planck Institute for the Physics of Complex Systems

Presentation transcript:

Semiclassical dynamics in the presence of loss and gain Eva-Maria Graefe Department of Mathematics, Imperial College London, UK Non-Hermitian Photonics in Complex Media: PT-symmetry and beyond Heraklion, Crete, June 2016 joint work with Roman Schubert, Hans Jürgen Korsch, and Alexander Rush Department of Mathematics, University of Bristol, UK Department of Physics, TU Kaiserslautern, Germany Department of Mathematics, Imperial College London, UK

Outline  Quasiclassical description of Bloch oscillations in non-Hermitian lattices: Tight-binding Hamiltonian, Bloch oscillations, classical explanation, non-Hermitian case  Beam dynamics with gain and loss: Schrödinger dynamics in wave guides, semiclassical limit with Gaussians wave packets, a PT-symmetric wave guide  Semiclassical limit of non-Hermitian quantum systems – a general structure

Beam propagation in optical waveguides  Propagation of electric field amplitude in paraxial approximation in direction : Effective Reference refractive index Refractive index modulation in x direction:  Gaussian approximation yields “geometric optics” beam dynamics

From quantum to classical dynamics  Classical Hamiltonian dynamics: Erwin Schrödinger Nobel Prize 1933 Sir William Rowan Hamilton  Quantum dynamics: Schrödinger equation  Semiclassical limit: Gaussian quantum wave packets move approximately according to classical dynamics

“Semiclassical” (Beam) dynamics  Initial Gaussian beam:  B encodes uncertainties: Hepp, Heller, Littlejohn 1970‘s

“Semiclassical” (Beam) dynamics  Initial Gaussian beam:  B encodes uncertainties:  Ansatz for time-evolved state: Hepp, Heller, Littlejohn 1970‘s

“Semiclassical” (Beam) dynamics  Taylor expansion of potential yields  Ansatz for time-evolved state: Hepp, Heller, Littlejohn 1970‘s

“Semiclassical” (Beam) dynamics  Taylor expansion of potential yields  Alternative “derivation”: Ehrenfest theorem  Ansatz for time-evolved state: Hepp, Heller, Littlejohn 1970‘s

 Complex refractive index models absorption and amplification Beam optics in the presence of loss and gain EMG, Rush, Schubert, arXiv:

 Initial Gaussian beam:  Ansatz for time-evolved state:  Complex refractive index models absorption and amplification Beam optics in the presence of loss and gain EMG, Rush, Schubert, arXiv:

Beam optics in the presence of loss and gain  Gaussian approximation and quadratic Taylor expansion around centre yields: EMG, Rush, Schubert, arXiv:

Example: PT-symmetric wave guide Gaussian approximation expected to be good for large EMG, Rush, Schubert, arXiv:

Example: PT-symmetric wave guide Guassian approximation (top) and exact numerical propagation (bottom), EMG, Rush, Schubert, arXiv:

Example: PT-symmetric wave guide Guassian approximation (top) and exact numerical propagation (bottom), EMG, Rush, Schubert, arXiv:

Beam optics without absorption EMG, Rush, Schubert, arXiv:

Beam optics with absorption EMG, Rush, Schubert, arXiv:

Outline  Quasiclassical description of Bloch oscillations in non-Hermitian lattices: Tight-binding Hamiltonian, Bloch oscillations, classical explanation, non-Hermitian case  Beam dynamics with gain and loss: Schrödinger dynamics in wave guides, semiclassical limit with Gaussians wave packets, a PT-symmetric wave guide  Semiclassical limit of non-Hermitian quantum systems – a general structure

“Semiclassical” dynamics – general structure  Ansatz for time-evolved state:  Time evolution with general non-Hermitian Hamiltonian:  Taylor expansion of H around centre of wave packet up to second order  Coupled dynamical equations for phase space coordinates and (co)variances

 With covariance matrix EMG, R. Schubert, PRA 83, (R) (2011), EMG, H.J. Korsch, and A. Rush, arXiv: “Semiclassical” dynamics – general structure

 With covariance matrix “Semiclassical” dynamics – general structure EMG, R. Schubert, PRA 83, (R) (2011), EMG, H.J. Korsch, and A. Rush, arXiv:

 With covariance matrix “Semiclassical” dynamics – general structure EMG, R. Schubert, PRA 83, (R) (2011), EMG, H.J. Korsch, and A. Rush, arXiv:

Hermitian part: symplectic flow Anti-Hermitian part: metric flow q q p p The generalised canonical equations Hamiltonian (conservative) dynamics Aims to drive the dynamics on the “direct” way towards a minimum of. EMG, M. Höning, and H. J. Korsch J. Phys. A 43, (2010)

 Dynamics of position and momentum  Coupled to covariance dynamics  Resulting dynamics of squared norm/total power: “Semiclassical” dynamics – general structure EMG, R. Schubert, PRA 83, (R) (2011), EMG, H.J. Korsch, and A. Rush, arXiv:

Outline  Quasiclassical description of Bloch oscillations in non-Hermitian lattices: Tight-binding Hamiltonian, Bloch oscillations, classical explanation, non-Hermitian case  Beam dynamics with gain and loss: Schrödinger dynamics in wave guides, semiclassical limit with Gaussians wave packets, a PT-symmetric wave guide  Semiclassical limit of non-Hermitian quantum systems – a general structure

Single-band tight-binding Hamiltonian On-site energy Tunneling/hopping between sites T. Hartmann, F. Keck, S. Mossmann, and H.J. Korsch, New J. Phys. 6 (2004) 2 Lattice site

Algebraic formulation  With the shift algebra

Algebraic formulation  Define quasimomentum operator via  With the shift algebra  “Conjugate” of the discrete position operator:

Bloch oscillations – quasiclassical explanation  Heisenberg equations of motion  Acceleration theorem:  Ehrenfest theorem:

Non-Hermitian tight-binding lattice  Quasiclassical dynamics? S. Longhi, PRA 92, (2015)

Non-Hermitian tight-binding lattice  Quasiclassical dynamics?  Modified Heisenberg equations of motion not directly useful… S. Longhi, PRA 92, (2015)

 Dynamics of position and momentum  Coupled to covariance dynamics  Resulting dynamics of squared norm/total power: EMG, H.J. Korsch, and A. Rush, arXiv: “Semiclassical” dynamics – general structure

Limit of narrow momentum packets  Can be analytically solved to yield:  Acceleration theorem: EMG, H.J. Korsch, and A. Rush, arXiv:

Limit of narrow momentum packets  Can be analytically solved to yield:  Acceleration theorem:  Dynamics of centre: Constant covariance Fieldfree dispersion relation: EMG, H.J. Korsch, and A. Rush, arXiv:

Limit of narrow momentum packets  Can be analytically solved to yield:  Acceleration theorem:  Dynamics of centre: Constant covariance Fieldfree dispersion relation:  Evolution of total power: EMG, H.J. Korsch, and A. Rush, arXiv:

Limit of narrow momentum packets  Can be analytically solved to yield:  Acceleration theorem:  Dynamics of centre: Constant covariance Fieldfree dispersion relation:  Evolution of total power:  Exact for vanishing momentum width! EMG, H.J. Korsch, and A. Rush, arXiv:

Example: Hatano-Nelson lattice  Simple mapping to Hermitian Hamiltonian and analytical solution  Classical Hamiltonian:  Experimental realisation in optical resonator structures proposed by Longhi EMG, H.J. Korsch, and A. Rush, arXiv:

Example: Hatano-Nelson lattice Propagation of (wide) Gaussian beam EMG, H.J. Korsch, and A. Rush, arXiv:

Breathing modes Propagation of single site initial state in Hermitian case Quasiclassical dynamics not valid, but can be explained as classical ensemble T. Hartmann, F. Keck, S. Mossmann, and H.J. Korsch, New J. Phys. 6 (2004) 2

Breathing modes in a Hatano-Nelson lattice EMG, H.J. Korsch, and A. Rush, arXiv:

Quasiclassical breathing mode  Interpret Fourier transform of initially localised state as (incoherent) ensemble of infinitely narrow momentum wavepackets! EMG, H.J. Korsch, and A. Rush, arXiv: Quantum propagation: Classical ensemble:

Summary  Quasiclassical description of Bloch oscillations in non-Hermitian lattices: Tight-binding Hamiltonian, Bloch oscillations, classical explanation, non-Hermitian case  Beam dynamics with gain and loss: Schrödinger dynamics in wave guides, semiclassical limit with Gaussians wave packets, a PT-symmetric wave guide  Semiclassical limit of non-Hermitian quantum systems – a general structure

Summary  Quasiclassical description of Bloch oscillations in non-Hermitian lattices: Tight-binding Hamiltonian, Bloch oscillations, classical explanation, non-Hermitian case  Beam dynamics with gain and loss: Schrödinger dynamics in wave guides, semiclassical limit with Gaussians wave packets, a PT-symmetric wave guide  Semiclassical limit of non-Hermitian quantum systems – a general structure Thank you for your attention!