Scattering into one-dimensional waveguides from a coherently-driven quantum-optical system

We develop a new computational tool and framework for characterizing the scattering of photons by energy-nonconserving Hamiltonians into unidirectional (chiral) waveguides, for example, with coherent pulsed excitation. The temporal waveguide modes are a natural basis for characterizing scattering in quantum optics, and afford a powerful technique based on a coarse discretization of time. This overcomes limitations imposed by singularities in the waveguide-system coupling. Moreover, the integrated discretized equations can be faithfully converted to a continuous-time result by taking the appropriate limit. This approach provides a complete solution to the scattered photon field in the waveguide, and can also be used to track system-waveguide entanglement during evolution. We further develop a direct connection between quantum measurement theory and evolution of the scattered field, demonstrating the correspondence between quantum trajectories and the scattered photon state. Our method is most applicable when the number of photons scattered is known to be small, i.e. for a single-photon or photon-pair source. We illustrate two examples: analytical solutions for short laser pulses scattering off a two-level system and numerically exact solutions for short laser pulses scattering off a spontaneous parametric downconversion (SPDC) or spontaneous four-wave mixing (SFWM) source. Finally, we note that our technique can easily be extended to systems with multiple ground states and generalized scattering problems with both finite photon number input and coherent state drive, potentially enhancing the understanding of, e.g., light-matter entanglement and photon phase gates.

[1]  K. Fischer Derivation of the quantum-optical master equation based on coarse-graining of time , 2017, Journal of Physics Communications.

[2]  Peter Michler,et al.  Quantum Dots for Quantum Information Technologies , 2017 .

[3]  Andrew G. White,et al.  Boson Sampling with Single-Photon Fock States from a Bright Solid-State Source. , 2016, Physical review letters.

[4]  Juan Jose Garcia-Ripoll Time evolution of Matrix Product States , 2006 .

[5]  I. Sagnes,et al.  Near-optimal single-photon sources in the solid state , 2015, Nature Photonics.

[6]  C. Noh,et al.  Diagrammatic approach to multiphoton scattering , 2017, 1702.01632.

[7]  E. Waks,et al.  A quantum phase switch between a single solid-state spin and a photon. , 2015, Nature nanotechnology.

[8]  Shanhui Fan,et al.  Input-output formalism for few-photon transport: A systematic treatment beyond two photons , 2015, 1502.06049.

[9]  E. Togan,et al.  Observation of entanglement between a quantum dot spin and a single photon , 2012, Nature.

[10]  A. LeClair,et al.  A one-dimensional model for n-level atoms coupled to an electromagnetic field , 1999 .

[11]  Y. Silberberg,et al.  High-NOON States by Mixing Quantum and Classical Light , 2010, Science.

[12]  V. Rupasov Complete integrability of the quasi-one-dimensional quantum model of Dicke superradiance , 1982 .

[13]  Min Xiao,et al.  Resonantly driven coherent oscillations in a solid-state quantum emitter , 2009 .

[14]  M. Kamp,et al.  Single Semiconductor Quantum Dots in Microcavities: Bright Sources of Indistinguishable Photons , 2015, 1502.00160.

[15]  J. Wierzbowski,et al.  Signatures of two-photon pulses from a quantum two-level system , 2017, Nature Physics.

[16]  Jesper Mork,et al.  Scattering of two photons on a quantum emitter in a one-dimensional waveguide: exact dynamics and induced correlations , 2014, 1409.1256.

[17]  D. Englund,et al.  Solid-state single-photon emitters , 2016, Nature Photonics.

[18]  J. Sipe,et al.  Spontaneous parametric down-conversion in waveguides: A backward Heisenberg picture approach , 2008 .

[19]  J. Vučković,et al.  Pulsed Rabi oscillations in quantum two-level systems: beyond the area theorem , 2017, 1708.05444.

[20]  S. Hughes,et al.  Influence of electron-acoustic phonon scattering on intensity power broadening in a coherently driven quantum-dot cavity system , 2011, 1109.6530.

[21]  J. Gea-Banacloche,et al.  Quantum multimode treatment of light scattering by an atom in a waveguide , 2016 .

[22]  SCATTERING THEORY OF OSCILLATOR DEFECTS IN AN OPTICAL FIBER , 1997, hep-th/9701016.

[23]  J. Eisert,et al.  Holographic quantum states. , 2010, Physical review letters.

[24]  M. Kamp,et al.  An electrically driven cavity-enhanced source of indistinguishable photons with 61% overall efficiency , 2016 .

[25]  J. Ignacio Cirac,et al.  Multiphoton-scattering theory and generalized master equations , 2015, 1507.08699.

[26]  A. Brańczyk,et al.  N-photon wave packets interacting with an arbitrary quantum system , 2012, 1202.3430.

[27]  Collett,et al.  Input and output in damped quantum systems: Quantum stochastic differential equations and the master equation. , 1985, Physical review. A, General physics.

[28]  Howard Mark Wiseman Quantum trajectories and feedback , 1994 .

[29]  Wang Yao,et al.  Theory of control of the spin-photon interface for quantum networks. , 2005, Physical review letters.

[30]  Michael Pepper,et al.  Electrically Driven Single-Photon Source , 2001, Science.

[31]  Daoyi Dong,et al.  Exact analysis of the response of quantum systems to two-photons using a QSDE approach , 2015, 1509.06934.

[32]  M. S. Zubairy,et al.  Photon transport in a one-dimensional nanophotonic waveguide QED system , 2016 .

[33]  Christian Schneider,et al.  Highly indistinguishable on-demand resonance fluorescence photons from a deterministic quantum dot micropillar device with 74% extraction efficiency. , 2015, Optics express.

[34]  C. P. Sun,et al.  Lehmann-Symanzik-Zimmermann reduction approach to multiphoton scattering in coupled-resonator arrays , 2008, 0809.1279.

[35]  S. Fan,et al.  Input-Output Formalism for Few-Photon Transport , 2017 .

[36]  H. Carmichael An open systems approach to quantum optics , 1993 .

[37]  Konstantinos G. Lagoudakis,et al.  Dynamical modeling of pulsed two-photon interference , 2016, 1608.07626.

[38]  B. Brecht,et al.  Photon temporal modes: a complete framework for quantum information science , 2015, 1504.06251.

[39]  P. Senellart,et al.  High-performance semiconductor quantum-dot single-photon sources. , 2017, Nature nanotechnology.

[40]  Peter Zoller,et al.  Photonic Circuits with Time Delays and Quantum Feedback. , 2016, Physical review letters.

[41]  Yoshihisa Yamamoto,et al.  Indistinguishable photons from a single-photon device , 2002, Nature.

[42]  P. Zoller,et al.  Delayed coherent quantum feedback from a scattering theory and a matrix product state perspective , 2017, 1706.07844.

[43]  Ben Q. Baragiola,et al.  Quantum trajectories for propagating Fock states , 2017, 1704.00101.

[44]  Ofer Firstenberg,et al.  Colloquium: Strongly interacting photons in one-dimensional continuum , 2016, 1603.06590.

[45]  F. Laussy,et al.  Emitters of N-photon bundles , 2013, Nature Photonics.

[46]  Mario Dagenais,et al.  Photon Antibunching in Resonance Fluorescence , 1977 .

[47]  M. Scully,et al.  The Quantum Theory of Light , 1974 .

[48]  Jian-Wei Pan,et al.  On-Demand Single Photons with High Extraction Efficiency and Near-Unity Indistinguishability from a Resonantly Driven Quantum Dot in a Micropillar. , 2016, Physical review letters.

[49]  C. Gardiner,et al.  Quantum Noise: A Handbook of Markovian and Non-Markovian Quantum Stochastic Methods with Applications to Quantum Optics , 2004 .

[50]  J. Sipe,et al.  Spontaneous parametric downconversion in waveguides: what's loss got to do with it? , 2014, 1407.4219.

[51]  P. Petroff,et al.  A quantum dot single-photon turnstile device. , 2000, Science.

[52]  Howard J. Carmichael,et al.  An Open Systems Approach to Quantum Optics: Lectures Presented at the Universite Libre De Bruxelles, October 28 to November 4, 1991 , 1993 .

[53]  Law,et al.  Continuous frequency entanglement: effective finite hilbert space and entropy control , 2000, Physical review letters.

[54]  V. Gritsev,et al.  Scattering of massless particles in one-dimensional chiral channel , 2012, 1203.0451.

[55]  J. Rarity,et al.  Photonic quantum technologies , 2009, 1003.3928.

[56]  Maira Amezcua,et al.  Quantum Optics , 2012 .

[57]  Effective formalism for open-quantum-system dynamics: Time-coarse-graining approach , 2017, 1709.00591.

[58]  J H Eberly,et al.  Analysis and interpretation of high transverse entanglement in optical parametric down conversion. , 2004, Physical review letters.

[59]  G. Johansson,et al.  Scattering of coherent pulses on a two-level system—single-photon generation , 2014, 1401.3707.

[60]  Valerio Scarani,et al.  Solving the scattering of N photons on a two-level atom without computation , 2016, 1603.02804.

[61]  Daniel J. Gauthier,et al.  Waveguide QED: Many-body bound-state effects in coherent and Fock-state scattering from a two-level system , 2010, 1009.5325.

[62]  Lorenzo Pavesi,et al.  Silicon Photonics III , 2016 .

[63]  R. Glauber The Quantum Theory of Optical Coherence , 1963 .

[64]  Stephen Hughes,et al.  Influence of electron-phonon scattering for an on-demand quantum dot single-photon source using cavity-assisted adiabatic passage , 2017, 1706.07521.

[65]  C. cohen-tannoudji,et al.  Atom-Photon Interactions: Basic Processes and Applications , 1992 .

[66]  S. Blundell,et al.  Quantum Field Theory for the Gifted Amateur , 2014 .

[67]  H. J. Carmichael,et al.  Open quantum systems with delayed coherent feedback , 2017, 1702.05776.

[68]  R. Glauber Coherent and incoherent states of the radiation field , 1963 .

[69]  P. Reineker,et al.  Multiphoton scattering in a one-dimensional waveguide with resonant atoms , 2008 .

[70]  S. Fan,et al.  Few-photon scattering and emission from low-dimensional quantum systems , 2018, Physical Review B.

[71]  J. Sipe,et al.  Asymptotic fields for a Hamiltonian treatment of nonlinear electromagnetic phenomena , 2012 .

[72]  P. Kok,et al.  Analytic few-photon scattering in waveguide QED , 2017, 1705.07016.

[73]  D. Bombardelli S-matrices and integrability , 2016, 1606.02949.

[74]  Franco Nori,et al.  QuTiP: An open-source Python framework for the dynamics of open quantum systems , 2011, Comput. Phys. Commun..

[75]  Alexander Y. Piggott,et al.  Nonclassical higher-order photon correlations with a quantum dot strongly coupled to a photonic-crystal nanocavity , 2013, 1307.3601.

[76]  Eigenstates of the Atom–Field Interaction and the Binding of Light in Photonic Crystals , 1997, hep-th/9706150.

[77]  Shanhui Fan,et al.  Input-output formalism for few-photon transport in one-dimensional nanophotonic waveguides coupled to a qubit , 2010, 1011.3296.

[78]  J. Ignacio Cirac,et al.  Quantum dynamics of propagating photons with strong interactions: a generalized input–output formalism , 2015, 1501.04427.

[79]  Hong,et al.  Measurement of subpicosecond time intervals between two photons by interference. , 1987, Physical review letters.

[80]  M. Steel,et al.  Effects of filtering on the purity of heralded single photons from parametric sources , 2017, 1705.10953.

[81]  T. Sarmiento,et al.  Ultrafast Polariton-Phonon Dynamics of Strongly Coupled Quantum Dot-Nanocavity Systems , 2015, 1503.05595.

[82]  Michael J. Strain,et al.  Qubit entanglement between ring-resonator photon-pair sources on a silicon chip , 2014, Nature Communications.

[83]  V. Gritsev,et al.  Quantum theory of light scattering in a one-dimensional channel: Interaction effect on photon statistics and entanglement entropy , 2015, 1504.03350.

[84]  P. Domokos,et al.  Quantum description of light-pulse scattering on a single atom in waveguides , 2002, quant-ph/0202005.

[85]  B. R. Mollow Power spectrum of light scattered by two-level systems , 1969 .

[86]  Dirk Englund,et al.  Efficient generation of single and entangled photons on a silicon photonic integrated chip , 2011 .

[87]  Francesco Petruccione,et al.  The Theory of Open Quantum Systems , 2002 .

[88]  C. Navarrete-Benlloch,et al.  Deterministic Down-Converter and Continuous Photon-Pair Source within the Bad-Cavity Limit. , 2016, Physical review letters.

[89]  J. P. Garrahan,et al.  Equivalence of matrix product ensembles of trajectories in open quantum systems. , 2015, Physical review. E, Statistical, nonlinear, and soft matter physics.

[90]  David Perez-Garcia,et al.  Continuum limits of matrix product states , 2018, Physical Review B.

[91]  Qiang Lin,et al.  Biphoton statistic of quantum light generated on a silicon chip , 2016, 1602.08057.

[92]  Jian-Wei Pan,et al.  On-demand semiconductor single-photon source with near-unity indistinguishability. , 2012, Nature nanotechnology.

[93]  J I Cirac,et al.  Continuous matrix product states for quantum fields. , 2010, Physical review letters.

[94]  J. O'Brien,et al.  Qubit entanglement between ring-resonator photon-pair sources on a silicon chip , 2015, Nature Communications.

[95]  K. Busch,et al.  Green's-function formalism for waveguide QED applications , 2015, 1509.08633.

[96]  J. E. Sipe,et al.  Spontaneous four-wave mixing in lossy microring resonators , 2015, 1502.05900.

[97]  B. R. Mollow Pure-state analysis of resonant light scattering: Radiative damping, saturation, and multiphoton effects , 1975 .

[98]  N. Gregersen,et al.  A highly efficient single-photon source based on a quantum dot in a photonic nanowire , 2010 .