Your search keyword '"Imamoglu, Atac"' showing total 308 results

51. Carrier-mediated optomechanical forces in semiconductor nanomembranes with coupled quantum wells

Author

Barg, Andreas, Midolo, Leonardo, Kiršanskė, Gabija, Tighineanu, Petru, Pregnolato, Tommaso, İmamoǧlu, Ataç, Lodahl, Peter, Schliesser, Albert, Stobbe, Søren, and Polzik, Eugene S.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

In the majority of optomechanical experiments, the interaction between light and mechanical motion is mediated by radiation pressure, which arises from momentum transfer of reflecting photons. This is an inherently weak interaction, and optically generated carriers in semiconductors have been predicted to be the mediator of different and potentially much stronger forces. Here we demonstrate optomechanical forces induced by electron-hole pairs in coupled quantum wells embedded into a free-free nanomembrane. We identify contributions from the deformation-potential and piezoelectric coupling and observe optically driven motion about three orders of magnitude larger than expected from radiation pressure. The amplitude and phase of the driven oscillations are controlled by an applied electric field, which tunes the carrier lifetime to match the mechanical period. Our work opens perspectives for not only enhancing the optomechanical interaction in a range of experiments, but also for interfacing mechanical objects with complex macroscopic quantum objects, such as excitonic condensates., Comment: 11 pages, 8 figures, 1 table; revised diffusion model, accepted version, added acknowledgement

Published

2017

52. Quantum interface between photonic and superconducting qubits

Author

Tsuchimoto, Yuta, Knüppel, Patrick, Delteil, Aymeric, Sun, Zhe, Kroner, Martin, and Imamoğlu, Ataç

Subjects

Quantum Physics

Abstract

We show that optically active coupled quantum dots embedded in a superconducting microwave cavity can be used to realize a fast quantum interface between photonic and transmon qubits. Single photon absorption by a coupled quantum dot results in generation of a large electric dipole, which in turn ensures efficient coupling to the microwave cavity. Using cavity parameters achieved in prior experiments, we estimate that bi-directional microwave-optics conversion in nanosecond timescales with efficiencies approaching unity is experimentally feasible with current technology. We also outline a protocol for in-principle deterministic quantum state transfer from a time-bin photonic qubit to a transmon qubit. Recent advances in quantum dot based quantum photonics technologies indicate that the scheme we propose could play a central role in connecting quantum nodes incorporating cavity-coupled superconducting qubits.

Published

2017

53. Signatures of a dissipative phase transition in photon correlation measurements

Author

Fink, Thomas, Schade, Anne, Höfling, Sven, Schneider, Christian, and İmamoğlu, Ataç

Subjects

Quantum Physics

Abstract

Understanding and characterizing phase transitions in driven-dissipative systems constitutes a new frontier for many-body physics. A generic feature of dissipative phase transitions is a vanishing gap in the Liouvillian spectrum, which leads to long-lived deviations from the steady-state as the system is driven towards the transition. Here, we show that photon correlation measurements can be used to characterize the corresponding critical slowing down of nonequilibrium dynamics. We focus on the extensively studied phenomenon of optical bistability in GaAs cavity-polaritons, which can be described as a first-order dissipative phase transition. Increasing the excitation strength towards the bistable range results in an increasing photon-bunching signal along with a decay time that is prolonged by more than nine orders of magnitude as compared to that of low density polaritons. In the limit of strong polariton interactions leading to pronounced quantum fluctuations, the mean-field bistability threshold is washed out. Nevertheless, the scaling of the Liouvillian gap closing as thermodynamic limit is approached provides a signature of the emerging dissipative phase transition. Our results establish photon correlation measurements as an invaluable tool for studying dynamical properties of dissipative phase transitions without requiring phase-sensitive interferometric measurements., Comment: 10 pages, 5 figures

Published

2017

54. Realization of an atomically thin mirror using monolayer MoSe2

Author

Back, Patrick, Ijaz, Aroosa, Zeytinoglu, Sina, Kroner, Martin, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics, Quantum Physics

Abstract

Advent of new materials such as van der Waals heterostructures, propels new research directions in condensed matter physics and enables development of novel devices with unique functionalities. Here, we show experimentally that a monolayer of MoSe2 embedded in a charge controlled heterostructure can be used to realize an electrically tunable atomically-thin mirror, that effects 90% extinction of an incident field that is resonant with its exciton transition. The corresponding maximum reflection coefficient of 45% is only limited by the ratio of the radiative decay rate to the linewidth of exciton transition and is independent of incident light intensity up to 400 Watts/cm2. We demonstrate that the reflectivity of the mirror can be drastically modified by applying a gate voltage that modifies the monolayer charge density. Our findings could find applications ranging from fast programmable spatial light modulators to suspended ultra-light mirrors for optomechanical devices.

Published

2017

55. Deterministic entanglement between a propagating photon and a singlet--triplet qubit in an optically active quantum dot molecule

Author

Delley, Yves L., Kroner, Martin, Fält, Stefan, Wegscheider, Werner, and İmamoğlu, Ataç

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Two-electron charged self-assembled quantum dot molecules exhibit a decoherence-avoiding singlet-triplet qubit subspace and an efficient spin-photon interface. We demonstrate quantum entanglement between emitted photons and the spin-qubit after the emission event. We measure the overlap with a fully entangled state to be $69.5\pm2.7\,\%$, exceeding the threshold of $50\,\%$ required to prove the non-separability of the density matrix of the system. The photonic qubit is encoded in two photon states with an energy difference larger than the timing resolution of existing detectors. We devise a novel heterodyne detection method, enabling projective measurements of such photonic color qubits along any direction on the Bloch sphere.

Published

2017

56. Squeezed thermal reservoirs as a resource for a nano-mechanical engine beyond the Carnot limit

Author

Klaers, Jan, Faelt, Stefan, Imamoglu, Atac, and Togan, Emre

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics

Abstract

The efficient conversion of thermal energy to mechanical work by a heat engine is an ongoing technological challenge. Since the pioneering work of Carnot, it is known that the efficiency of heat engines is bounded by a fundamental upper limit, the Carnot limit. Theoretical studies suggest that heat engines may be operated beyond the Carnot limit by exploiting stationary, non-equilibrium reservoirs that are characterized by a temperature as well as further parameters. In a proof-of-principle experiment, we demonstrate that the efficiency of a nano-beam heat engine coupled to squeezed thermal noise is not bounded by the standard Carnot limit. Remarkably, we also show that it is possible to design a cyclic process that allows for extraction of mechanical work from a single squeezed thermal reservoir. Our results demonstrate a qualitatively new regime of non-equilibrium thermodynamics at small scales and provide a new perspective on the design of efficient, highly miniaturized engines., Comment: 5 pages, 3 figures

Published

2017

57. Atomically thin semiconductors as nonlinear mirrors

Author

Zeytinoglu, Sina, Roth, Charlaine, Huber, Sebastian, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We show that a transition metal dichalcogenide monolayer with a radiatively broadened exciton resonance would exhibit perfect extinction of a transmitted field. This result holds for s- or p-polarized weak resonant light fields at any incidence angle, due to the conservation of in-plane momentum of excitons and photons in a flat defect-free two dimensional crystal. In contrast to extinction experiments with single quantum emitters, exciton-exciton interactions lead to an enhancement of reflection with increasing power for incident fields that are blue detuned with respect to the exciton resonance. We show that the interactions limit the maximum reflection that can be achieved by depleting the incoming coherent state into an outgoing two-mode squeezed state., Comment: Comments welcome

Published

2017

58. Realization of a cascaded quantum system: heralded absorption of a single photon qubit by a single-electron charged quantum dot

Author

Delteil, Aymeric, Sun, Zhe, Fält, Stefan, and Imamoğlu, Ataç

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

Photonic losses pose a major limitation for implementation of quantum state transfer between nodes of a quantum network. A measurement that heralds successful transfer without revealing any information about the qubit may alleviate this limitation. Here, we demonstrate heralded absorption of a single photonic qubit generated by a single neutral quantum dot, by a single-electron charged quantum dot that is located 5 meters away. The transfer of quantum information to the spin degree of freedom takes place upon emission of a photon: for a properly chosen or prepared quantum dot, detection of this photon yields no information about the qubit. We show that this process can be combined with local operations optically performed on the destination node, by measuring classical correlations between the absorbed photon color and the final state of the electron spin. Our work suggests alternative avenues for realization of quantum information protocols based on cascaded quantum systems.

Published

2017

59. High-Order Multipole Radiation from Quantum Hall States in Dirac Materials

Author

Gullans, Michael J., Taylor, Jacob M., Imamoglu, Atac, Ghaemi, Pouyan, and Hafezi, Mohammad

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics, Quantum Physics

Abstract

We investigate the optical response of strongly disordered quantum Hall states in two-dimensional Dirac materials and find qualitatively different effects in the radiation properties of the bulk versus the edge. We show that the far-field radiation from the edge is characterized by large multipole moments (> 50) due to the efficient transfer of angular momentum from the electrons into the scattered light. The maximum multipole transition moment is a direct measure of the coherence length of the edge states. Accessing these multipole transitions would provide new tools for optical spectroscopy and control of quantum Hall edge states. On the other hand, the far-field radiation from the bulk appears as random dipole emission with spectral properties that vary with the local disorder potential. We determine the conditions under which this bulk radiation can be used to image the disorder landscape. Such optical measurements can probe sub-micron length scales over large areas and provide complementary information to scanning probe techniques. Spatially resolving this bulk radiation would serve as a novel probe of the percolation transition near half-filling., Comment: v2: 8 pages, 4 figures

Published

2017

60. Giant paramagnetism induced valley polarization of electrons in charge-tunable monolayer MoSe2

Author

Back, Patrick, Sidler, Meinrad, Cotlet, Ovidiu, Srivastava, Ajit, Takemura, Naotomo, Kroner, Martin, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

For applications exploiting the valley pseudospin degree of freedom in transition metal dichalcogenide monolayers, efficient preparation of electrons or holes in a single valley is essential. Here, we show that a magnetic field of 7 Tesla leads to a near-complete valley polarization of electrons in MoSe2 monolayer with a density 1.6x10^{12} cm^{-2}; in the absence of exchange interactions favoring single-valley occupancy, a similar degree of valley polarization would have required a pseudospin g-factor exceeding 40. To investigate the magnetic response, we use polarization resolved photoluminescence as well as resonant reflection measurements. In the latter, we observe gate voltage dependent transfer of oscillator strength from the exciton to the attractive-Fermi-polaron: stark differences in the spectrum of the two light helicities provide a confirmation of valley polarization. Our findings suggest an interaction induced giant paramagnetic response of MoSe2, which paves the way for valleytronics applications.

Published

2017

61. Polaron-Polaritons in the Integer and Fractional Quantum Hall Regimes

Author

Ravets, Sylvain, Knüppel, Patrick, Faelt, Stefan, Kroner, Martin, Wegscheider, Werner, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Elementary quasi-particles in a two dimensional electron system can be described as exciton-polarons since electron-exciton interactions ensures dressing of excitons by Fermi-sea electron-hole pair excitations. A relevant open question is the modification of this description when the electrons occupy flat-bands and electron-electron interactions become prominent. Here, we perform cavity spectroscopy of a two dimensional electron system in the strong-coupling regime where polariton resonances carry signatures of strongly correlated quantum Hall phases. By measuring the evolution of the polariton splitting under an external magnetic field, we demonstrate the modification of electron-exciton interactions that we associate with phase space filling at integer filling factors and polaron dressing at fractional filling factors. The observed non-linear behavior shows great promise for enhancing polariton-polariton interactions., Comment: 6 pages, 3 figures

Published

2017

62. Electrically tunable artificial gauge potential for polaritons

Author

Lim, Hyang-Tag, Togan, Emre, Kroner, Martin, Miguel-Sanchez, Javier, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Neutral particles subject to artificial gauge potentials can behave as charged particles in magnetic fields. This fascinating premise has led to demonstrations of one-way waveguides, topologically protected edge states and Landau levels for photons. In ultracold neutral atoms effective gauge fields have allowed the emulation of matter under strong magnetic fields leading to realization of Harper-Hofstadter and Haldane models. Here we show that application of perpendicular electric and magnetic fields effects a tuneable artificial gauge potential for two-dimensional microcavity exciton polaritons. For verification, we perform interferometric measurement of the associated phase accumulated during coherent polariton transport. Since the gauge potential originates from the magnetoelectric Stark effect, it can be realized for photons strongly coupled to excitations in any polarizable medium. Together with strong polariton- polariton interactions and engineered polariton lattices, artificial gauge fields could play a key role in investigation of non-equilibrium dynamics of strongly correlated photons., Comment: 12 pages, 3 figures. Supplementary information

Published

2016

63. Engineering matter interactions using squeezed vacuum

Author

Zeytinoglu, Sina, Imamoglu, Atac, and Huber, Sebastian

Subjects

Condensed Matter - Quantum Gases

Abstract

Virtually all interactions that are relevant for atomic and condensed matter physics are mediated by quantum fluctuations of the electromagnetic field vacuum. Consequently, controlling the vacuum fluctuations can be used to engineer the strength and the range of interactions. Recent experiments have used this premise to demonstrate novel quantum phases or entangling gates by embedding electric dipoles in photonic cavities or waveguides, which modify the electromagnetic fluctuations. Here, we show theoretically that the enhanced fluctuations in the anti-squeezed quadrature of a squeezed vacuum state allows for engineering interactions between electric dipoles without the need for a photonic structure. Thus, the strength and range of the interactions can be engineered in a time-dependent way by changing the spatial profile of the squeezed vacuum in a travelling-wave geometry, which also allows the implementation of chiral dissipative interactions. Using experimentally realized squeezing parameters and including realistic losses, we predict single atom cooperativities $C$ of up to 10 for the squeezed vacuum enhanced interactions.

Published

2016

64. Measurement of spin coherence using Raman scattering

Author

Sun, Zhe, Delteil, Aymeric, Faelt, Stefan, and Imamoglu, Atac

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Ramsey interferometry provides a natural way to determine the coherence time of most qubit systems. Recent experiments on quantum dots however, demonstrated that dynamical nuclear spin polarization can strongly influence the measurement process, making it difficult to extract the $T_2^*$ coherence time using optical Ramsey pulses. Here, we demonstrate an alternative method for spin coherence measurement that is based on first-order coherence of photons generated in spin-flip Raman scattering. We show that if a quantum emitter is driven by a weak monochromatic laser, Raman coherence is determined exclusively by spin coherence, allowing for a direct determination of spin $T_2^*$ time. When combined with coherence measurements on Rayleigh scattered photons, our technique enables us to identify coherent and incoherent contributions to resonance fluorescence, and to minimize the latter. We verify the validity of our technique by comparing our results to those determined from Ramsey interferometry for electron and heavy-hole spins., Comment: 8 pages, 6 figures

Published

2016

65. Fermi polaron-polaritons in charge-tunable atomically thin semiconductors

Author

Sidler, Meinrad, Back, Patrick, Cotlet, Ovidiu, Srivastava, Ajit, Fink, Thomas, Kroner, Martin, Demler, Eugene, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The dynamics of a mobile quantum impurity in a degenerate Fermi system is a fundamental problem in many-body physics. The interest in this field has been renewed due to recent ground-breaking experiments with ultra-cold Fermi gases. Optical creation of an exciton or a polariton in a two-dimensional electron system embedded in a microcavity constitutes a new frontier for this field due to an interplay between cavity-coupling favoring ultra-low mass polariton formation and exciton-electron interactions leading to polaron or trion formation. Here, we present cavity spectroscopy of gate-tunable monolayer MoSe$_2$ exhibiting strongly bound trion and polaron resonances, as well as non-perturbative coupling to a single microcavity mode. As the electron density is increased, the oscillator strength determined from the polariton splitting is gradually transferred from the higher-energy repulsive-exciton-polaron resonance to the lower-energy attractive-polaron manifold. Simultaneous observation of polariton formation in both attractive and repulsive branches indicate a new regime of polaron physics where the polariton impurity mass is much smaller than that of the electrons. Our findings shed new light on optical response of semiconductors in the presence of free carriers by identifying the Fermi polaron nature of excitonic resonances and constitute a first step in investigation of a new class of degenerate Bose-Fermi mixtures.

Published

2016

66. Superconductivity and other phase transitions in a hybrid Bose-Fermi mixture formed by a polariton condensate and an electron system in two dimensions

Author

Cotleţ, Ovidiu, Zeytinoǧlu, Sina, Sigrist, Manfred, Demler, Eugene, and Imamoǧlu, Ataç

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity, Quantum Physics

Abstract

Interacting Bose-Fermi systems play a central role in condensed matter physics. Here, we analyze a novel Bose-Fermi mixture formed by a cavity exciton-polariton condensate interacting with a two-dimensional electron system. We show that that previous predictions of superconductivity [F.P. Laussy, Phys. Rev. Lett. 10, 104 (2010)] and excitonic supersolid formation [I.A. Shelykh, Phys. Rev. Lett. 14, 105 (2010)] in this system are closely intertwined- resembling the predictions for strongly correlated electron systems such as high temperature superconductors. In stark contrast to a large majority of Bose-Fermi systems analyzed in solids and ultracold atomic gases, the renormalized interaction between the polaritons and electrons in our system is long-ranged and strongly peaked at a tunable wavevector, which can be rendered incommensurate with the Fermi momentum. We analyze the prospects for experimental observation of superconductivity and find that critical temperatures on the order of a few Kelvins can be achieved in heterostructures consisting of transition metal dichalcogenide monolayers that are embedded in an open cavity structure. All optical control of superconductivity in semiconductor heterostructures could enable the realization of new device concepts compatible with semiconductor nanotechnology. In addition the possibility to interface quantum Hall physics, superconductivity and nonequilibrium polariton condensates is likely to provide fertile ground for investigation of completely new physical phenomena., Comment: 20 pages, 6 figures

Published

2015

67. Signatures of Bloch-band geometry on excitons: non-hydrogenic spectra in transition metal dichalcogenides

Author

Srivastava, Ajit and Imamoğlu, Ataç

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The geometry of electronic bands in a solid can drastically alter single-particle charge and spin transport. We show here that collective optical excitations arising from Coulomb interactions also exhibit unique signatures of Berry curvature and quantum geometric tensor. A non-zero Berry curvature mixes and lifts the degeneracy of $l \neq 0$ states, leading to a time-reversal-symmetric analog of the orbital Zeeman effect. The quantum geometric tensor, on the other hand, leads to $l$-dependent shifts of exciton states that is analogous to the Lamb shift. Our results provide an explanation of the non-hydrogenic exciton spectrum recently calculated for transition metal dichalcogenides. Numerically, we find a Berry curvature induced splitting of $\sim 10$ meV between the $2p_x \pm i2p_y$ states of WSe$_2$., Comment: 5 pages, 2 figures

Published

2015

68. Generation of heralded entanglement between distant hole spins

Author

Delteil, Aymeric, Zhe, Sun, Gao, Wei-bo, Togan, Emre, Faelt, Stefan, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Quantum entanglement emerges naturally in interacting quantum systems and plays a central role in quantum information processing. Remarkably, it is possible to generate entanglement even in the absence of direct interactions: provided that which path information is erased, weak spin-state dependent light scattering can be used to project two distant spins onto a maximally entangled state upon detection of a single photon. Even though this approach is necessarily probabilistic, successful generation of entanglement is heralded by the photon detection event. Here, we demonstrate heralded quantum entanglement of two quantum dot heavy-hole spins separated by 5 meters using single-photon interference. Thanks to the long coherence time of hole spins and the efficient spin-photon interface provided by self-assembled quantum dots embedded in leaky microcavity structures, we generate 2300 entangled spin pairs per second, which represents an improvement approaching three orders of magnitude as compared to prior experiments. Delayed two-photon interference scheme we developed allows for efficient verification of quantum correlations. Our results lay the groundwork for the realization of quantum networks in semiconductor nanostructures. Combined with schemes for transferring quantum information to a long-lived memory qubit, fast entanglement generation we demonstrate could also impact quantum repeater architectures., Comment: 12 pages, 3 figures

Published

2015

69. Real-time monitoring of L\'evy flights in a single quantum system

Author

Issler, Mena, Höller, Judith, and Imamoğlu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

L\'evy flights are random walks where the dynamics is dominated by rare events. Even though they have been studied in vastly different physical systems, their observation in a single quantum system has remained elusive. Here we analyze a periodically driven open central spin system and demonstrate theoretically that the dynamics of the spin environment exhibits L\'evy flights. For the particular realization in a single-electron charged quantum dot driven by periodic resonant laser pulses, we use Monte Carlo simulations to confirm that the long waiting times between successive nuclear spin flip events are governed by a power-law distribution; the corresponding exponent $\eta =-3/2$ can be directly measured in real-time by observing the waiting time distribution of successive photon emission events. Remarkably, the dominant intrinsic limitation of the scheme arising from nuclear quadrupole coupling can be minimized by adjusting the magnetic field or by implementing spin echo.

Published

2015

70. Optically Active Quantum Dots in Monolayer WSe$_2$

Author

Srivastava, Ajit, Sidler, Meinrad, Allain, Adrien V., Lembke, Dominik S., Kis, Andras, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Semiconductor quantum dots have emerged as promising candidates for implementation of quantum information processing since they allow for a quantum interface between stationary spin qubits and propagating single photons. In the meanwhile, transition metal dichalcogenide (TMD) monolayers have moved to the forefront of solid-state research due to their unique band structure featuring a large band gap with degenerate valleys and non-zero Berry curvature. Here we report the observation of quantum dots in monolayer tungsten-diselenide with an energy that is 20 to 100 meV lower than that of two dimensional excitons. Photon antibunching in second-order photon correlations unequivocally demonstrates the zero-dimensional anharmonic nature of these quantum emitters. The strong anisotropic magnetic response of the spatially localized emission peaks strongly indicates that radiative recombination stems from localized excitons that inherit their electronic properties from the host TMD. The large $\sim$ 1 meV zero-field splitting shows that the quantum dots have singlet ground states and an anisotropic confinement most likely induced by impurities or defects in the host TMD. Electrical control in van der Waals heterostructures and robust spin-valley degree of freedom render TMD quantum dots promising for quantum information processing.

Published

2014

71. Photo-activated biological processes as quantum measurements

Author

Imamoglu, Atac and Whaley, K. Birgitta

Subjects

Quantum Physics, Physics - Biological Physics, Quantitative Biology - Biomolecules

Abstract

We outline a framework for describing photo-activated biological reactions as generalized quantum measurements of external fields, for which the biological system takes on the role of a quantum meter. By using general arguments regarding the Hamiltonian that describes the measurement interaction, we identify the cases where it is essential for a complex chemical or biological system to exhibit non-equilibrium quantum coherent dynamics in order to achieve the requisite functionality. We illustrate the analysis by considering measurement of the solar radiation field in photosynthesis and measurement of the earth's magnetic field in avian magnetoreception., Comment: 9 pages, 2 figures

Published

2014

72. Valley Zeeman Effect in Elementary Optical Excitations of a Monolayer WSe2

Author

Srivastava, Ajit, Sidler, Meinrad, Allain, Adrien V., Lembke, Dominik S., Kis, Andras, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

A monolayer of a transition metal dichalcogenide (TMD) such as WSe$_2$ is a two-dimensional (2D) direct band-gap valley-semiconductor having an effective Honeycomb lattice structure with broken inversion symmetry. The inequivalent valleys in the Brillouin zone could be selectively addressed using circularly-polarized light fields, suggesting the possibility for magneto-optical measurement and manipulation of the valley pseudospin degree of freedom. Here we report such experiments that demonstrate the valley Zeeman effect -- strongly anisotropic lifting of the degeneracy of the valley pseudospin degree of freedom using an external magnetic field. While the valley-splitting measured using the exciton transition is consistent with the difference of the conduction and valence band orbital magnetic moments, the trion transition exhibits an unexpectedly large valley Zeeman effect which cannot be understood using an independent electron-hole picture. Instead, we find an explanation using the recently predicted large Berry curvature and the associated magnetic moment for the electron-hole exchange interaction modified trion dispersion. Our results raise the possibility of observing optical excitation induced valley Hall effect in monolayer TMDs or topological states of photons strongly coupled to trion excitations in a microcavity.

Published

2014

73. A single quantum dot as an optical thermometer for mK temperatures

Author

Haupt, Florian, Imamoglu, Atac, and Kroner, Martin

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Resonant laser spectroscopy of a negatively charged self-assembled quantum dot is utilized to measure the temperature of a three dimensional fermionic reservoir down to 100mK. With a magnetic field applied to the quantum dot the single charged ground state is split by the Zeeman energy. As the quantum dot is in tunnel contact with a thermal electron reservoir, a thermal occupation of the quantum dot spin states is enforced by co-tunneling processes. Resonant laser induced fluorescence is used in order to measure the thermal quantum dot spin state population., Comment: 11 pages, 4 figures

Published

2014

74. Polariton boxes in a tunable fiber cavity

Author

Besga, Benjamin, Vaneph, Cyril, Reichel, Jakob, Esteve, Jerome, Reinhard, Andreas, Miguel-Sanchez, Javier, Imamoglu, Atac, and Volz, Thomas

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

Cavity-polaritons in semiconductor photonic structures have emerged as a test bed for exploring non-equilibrium dynamics of quantum fluids in an integrated solid-state device setting. Several recent experiments demonstrated the potential of these systems for revealing quantum many-body physics in driven-dissipative systems. So far, all experiments have relied on fully integrated devices with little to no flexibility for modification of device properties. Here, we present a novel approach for realizing confined cavity-polaritons that enables in-situ tuning of the cavity length and thereby of the polariton energy and lifetime. Our setup is based on a versatile semi-integrated low-temperature fiber-cavity platform, which allows us to demonstrate the formation of confined polaritons (or polariton boxes) with unprecedented quality factors. At high pump powers, we observe clear signatures of polariton lasing. In the strong-confinement limit, the fiber-cavity system could enable the observation of the polariton-blockade effect.

Published

2013

75. Observation of quantum jumps of a single quantum dot spin using sub-microsecond single-shot optical readout

Author

Delteil, Aymeric, Gao, Wei-bo, Fallahi, Parisa, Miguel-Sanchez, Javier, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Single-shot read-out of individual qubits is typically the slowest process among the elementary single- and two-qubit operations required for quantum information processing. Here, we use resonance fluorescence from a single-electron charged quantum dot to read-out the spin-qubit state in 800 nanoseconds with a fidelity exceeding 80%. Observation of the spin evolution on longer timescales reveals quantum jumps of the spin state: we use the experimentally determined waiting-time distribution to characterize the quantum jumps. Embedding a quantum dot in a photonic nanostructure could be used to enhance the collection efficiency by a factor of 10, enabling single-shot read-out with a fidelity exceeding 97%., Comment: 5 pages, 3 figures

Published

2013

76. Dissipative Phase Transition in Central Spin Systems

Author

Kessler, Eric M., Giedke, Geza, Imamoglu, Atac, Yelin, Susanne F., Lukin, Mikhail D., and Cirac, J. Ignacio

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate dissipative phase transitions in an open central spin system. In our model the central spin interacts coherently with the surrounding many-particle spin environment and is subject to coherent driving and dissipation. We develop analytical tools based on a self-consistent Holstein-Primakoff approximation that enable us to determine the complete phase diagram associated with the steady states of this system. It includes first and second-order phase transitions, as well as regions of bistability, spin squeezing and altered spin pumping dynamics. Prospects of observing these phenomena in systems such as electron spins in quantum dots or NV centers coupled to lattice nuclear spins are briefly discussed., Comment: 23 pages, 11 figures, typos corrected

Published

2012

77. Nuclear spin physics in quantum dots: an optical investigation

Author

Urbaszek, Bernhard, Marie, Xavier, Amand, Thierry, Krebs, Olivier, Voisin, Paul, Maletinsky, Patrick, Hogele, Alexander, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The mesoscopic spin system formed by the 10E4-10E6 nuclear spins in a semiconductor quantum dot offers a unique setting for the study of many-body spin physics in the condensed matter. The dynamics of this system and its coupling to electron spins is fundamentally different from its bulk counter-part as well as that of atoms due to increased fluctuations that result from reduced dimensions. In recent years, the interest in studying quantum dot nuclear spin systems and their coupling to confined electron spins has been fueled by its direct implication for possible applications of such systems in quantum information processing as well as by the fascinating nonlinear (quantum-)dynamics of the coupled electron-nuclear spin system. In this article, we review experimental work performed over the last decades in studying this mesoscopic,coupled electron-nuclear spin system and discuss how optical addressing of electron spins can be exploited to manipulate and read-out quantum dot nuclei. We discuss how such techniques have been applied in quantum dots to efficiently establish a non-zero mean nuclear spin polarization and, most recently, were used to reduce fluctuations of the average quantum dot nuclear spin orientation. Both results in turn have important implications for the preservation of electron spin coherence in quantum dots, which we discuss. We conclude by speculating how this recently gained understanding of the quantum dot nuclear spin system could in the future enable experimental observation of quantum-mechanical signatures or possible collective behavior of mesoscopic nuclear spin ensembles., Comment: 61 pages, 45 figures, updated reference list, corrected typographical errors

Published

2012

78. Ultrafast all-optical switching by single photons

Author

Volz, Thomas, Reinhard, Andreas, Winger, Martin, Badolato, Antonio, Hennessy, Kevin J., Hu, Evelyn L., and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics, Quantum Physics

Abstract

An outstanding goal in quantum optics is the realization of fast optical non-linearities at the single-photon level. Such non-linearities would allow for the realization of optical devices with new functionalities such as a single-photon switch/transistor or a controlled-phase gate, which could form the basis of future quantum optical technologies. While non-linear optics effects at the single-emitter level have been demonstrated in different systems, including atoms coupled to Fabry-Perot or toroidal micro-cavities, super-conducting qubits in strip-line resonators or quantum dots (QDs) in nano-cavities, none of these experiments so far has demonstrated single-photon switching on ultrafast timescales. Here, we demonstrate that in a strongly coupled QD-cavity system the presence of a single photon on one of the fundamental polariton transitions can turn on light scattering on a transition from the first to the second Jaynes-Cummings manifold with a switching time of 20 ps. As an additional device application, we use this non-linearity to implement a single-photon pulse-correlator. Our QD-cavity system could form the building-block of future high-bandwidth photonic networks operating in the quantum regime.

Published

2011

79. Strongly correlated photons on a chip

Author

Reinhard, Andreas, Volz, Thomas, Winger, Martin, Badolato, Antonio, Hennessy, Kevin J., Hu, Evelyn L., and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics, Quantum Physics

Abstract

Optical non-linearities at the single-photon level are key ingredients for future photonic quantum technologies. Prime candidates for the realization of strong photon-photon interactions necessary for implementing quantum information processing tasks as well as for studying strongly correlated photons in an integrated photonic device setting are quantum dots embedded in photonic crystal nanocavities. Here, we report strong quantum correlations between photons on picosecond timescales. We observe (a) photon antibunching upon resonant excitation of the lowest-energy polariton state, proving that the first cavity photon blocks the subsequent injection events, and (b) photon bunching when the laser field is in two-photon resonance with the polariton eigenstates of the second Jaynes-Cummings manifold, demonstrating that two photons at this color are more likely to be injected into the cavity jointly, than they would otherwise. Together,these results demonstrate unprecedented strong single-photon non-linearities, paving the way for realizing a single-photon transistor or a quantum optical Josephson interferometer.

Published

2011

80. Hyperfine interaction dominated dynamics of nuclear spins in self-assembled quantum dots

Author

Latta, Christian, Srivastava, Ajit, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We measure the dynamics of nuclear spins in a self-assembled quantum dot at a magnetic field of 5 Tesla and identify two distinct mechanisms responsible for the decay of the Overhauser field. We attribute a temperature-independent decay which lasts ~100 seconds to intra-dot diffusion induced by hyperfine-mediated indirect nuclear spin interaction. In addition, we observe a gate-voltage and temperature dependent decay stemming from co-tunneling mediated nuclear spin flip processes. By adjusting the gate-voltage and lowering the electron temperature to ~200 milliKelvin, we prolong the corresponding decay time to ~30 hours. Our measurements indicate possibilities for exploring quantum dynamics of the central spin model using a single self-assembled quantum dot.

Published

2011

81. Quantum quench of Kondo correlations in optical absorption

Author

Latta, Christian, Haupt, Florian, Hanl, Markus, Weichselbaum, Andreas, Claassen, Martin, Wuester, Wolf, Fallahi, Parisa, Faelt, Stefan, Glazman, Leonid, von Delft, Jan, Türeci, Hakan E., and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

The interaction between a single confined spin and the spins of a Fermionic reservoir leads to one of the most spectacular phenomena of many body physics -- the Kondo effect. Here we report the observation of Kondo correlations in optical absorption measurements on a single semiconductor quantum dot tunnel-coupled to a degenerate electron gas. In stark contrast to transport experiments, absorption of a single photon leads to an abrupt change in the system Hamiltonian and a quantum quench of Kondo correlations. By inferring the characteristic power law exponents from the experimental absorption line-shapes, we find a unique signature of the quench in the form of an Anderson orthogonality catastrophe, originating from a vanishing overlap between the initial and final many-body wave-functions. We also show that the power-law exponents that determine the degree of orthogonality can be tuned by applying an external magnetic field which gradually turns the Kondo correlations off. Our experiments demonstrate that optical measurements on single artificial atoms offer new perspectives on many-body phenomena previously studied exclusively using transport spectroscopy. Moreover, they initiate a new paradigm for quantum optics where many-body physics influences electric field and intensity correlations.

Published

2011

82. Localization of Toric Code Defects

Author

Stark, Cyril, Pollet, Lode, Imamoglu, Atac, and Renner, Renato

Subjects

Quantum Physics

Abstract

We explore the possibility of passive error correction in the toric code model. We first show that even coherent dynamics, stemming from spin interactions or the coupling to an external magnetic field, lead to logical errors. We then argue that Anderson localization of the defects, arising from unavoidable fluctuations of the coupling constants, provides a remedy. This protection is demonstrated using general analytical arguments that are complemented with numerical results which demonstrate that self-correcting memory can in principle be achieved in the limit of a nonzero density of identical defects., Comment: Author added (Lode Pollet). Quantum Monte Carlo simulation for the analsis of positive defect densities added. Correction of the proof of Theorem 1 and strengthening of the statement of Theorem 1

Published

2011

83. Nuclear spin cooling using Overhauser field selective coherent population trapping

Author

Issler, Mena, Kessler, Eric, Giedke, Geza, Yelin, Susanne, Cirac, Ignacio, Lukin, Mikhail, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Hyperfine interactions with a nuclear spin environment fundamentally limit the coherence properties of confined electron spins in the solid-state. Here, we show that a quantum interference effect in optical absorption from two electronic spin states of a solid-state emitter can be used to prepare the surrounding environment of nuclear spins in well-defined states, thereby suppressing electronic spin dephasing. The evolution of the coupled electron-nuclei system into a coherent population trapping state by optical excitation induced nuclear spin diffusion can be described in terms of Levy flights, in close analogy with sub-recoil laser cooling of atoms. The large difference in electronic and nuclear time scales simultaneously allow for a measurement of the magnetic field produced by nuclear spins, making it possible to turn the lasers that cause the anomalous spin diffusion process off when the strength of the resonance fluorescence reveals that the nuclear spins are in the desired narrow state., Comment: 11 pages, 3 figures

Published

2010

84. On the origin of strong photon antibunching in weakly nonlinear photonic molecules

Author

Bamba, Motoaki, Imamoglu, Atac, Carusotto, Iacopo, and Ciuti, Cristiano

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

In a recent work [T. C. H. Liew and V. Savona, Phys. Rev. Lett. {\bf104}, 183601 (2010)] it was numerically shown that in a photonic 'molecule' consisting of two coupled cavities, near-resonant coherent excitation could give rise to strong photon antibunching with a surprisingly weak nonlinearity. Here, we show that a subtle quantum interference effect is responsible for the predicted efficient photon blockade effect. We analytically determine the optimal on-site nonlinearity and frequency detuning between the pump field and the cavity mode. We also highlight the limitations of the proposal and its potential applications in demonstration of strongly correlated photonic systems in arrays of weakly nonlinear cavities.

Published

2010

85. Feshbach blockade: single-photon nonlinear optics using resonantly enhanced cavity-polariton scattering from biexciton states

Author

Carusotto, Iacopo, Volz, Thomas, and Imamoglu, Atac

Subjects

Condensed Matter - Quantum Gases

Abstract

We theoretically demonstrate how the resonant coupling between a pair of cavity-polaritons and a biexciton state can lead to a large single-photon Kerr nonlinearity in a semiconductor solid-state system. A fully analytical model of the scattering process between a pair of cavity-polaritons is developed, which explicitly includes the biexcitonic intermediate state. A dramatic enhancement of the polariton-polariton interactions is predicted in the vicinity of the biexciton Feshbach resonance. Application to the generation of non-classical light from polariton dots is discussed.

Published

2010

86. Solid-State Spin-Photon Quantum Interface without Spin-Orbit Coupling

Author

Claassen, Martin, Türeci, Hakan E., and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We show that coherent optical manipulation of a single confined spin is possible even in the absence of spin-orbit coupling. To this end, we consider the non-Markovian dynamics of a single valence orbital hole spin that has optically induced spin exchange coupling to a low temperature partially polarized electron gas. We show that the fermionic nature of the reservoir induces a coherent component to the hole spin dynamics that does not generate entanglement with the reservoir modes. We analyze in detail the competition of this reservoir-assisted coherent contribution with dissipative components displaying markedly different behavior at different time scales and determine the fidelity of optically controlled spin rotations., Comment: 4 pages, 3 figures

Published

2009

87. Resolution of the mystery of counter-intuitive photon correlations in far off-resonance emission from a quantum dot-cavity system

Author

Winger, Martin, Volz, Thomas, Tarel, Guillaume, Portolan, Stefano, Badolato, Antonio, Hennessy, Kevin, Hu, Evelyn, Beveratos, Alexios, Finley, Jonathan, Savona, Vincenzo, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Cavity quantum-electrodynamics experiments using an atom coupled to a single radiation-field mode have played a central role in testing foundations of quantum mechanics, thus motivating solid-state implementations using single quantum dots coupled to monolithic nano-cavities. In stark contrast to their atom based counterparts, the latter experiments revealed strong cavity emission, even when the quantum dot is far off resonance. Here we present experimental and theoretical results demonstrating that this effect arises from the mesoscopic nature of quantum dot confinement, ensuring the presence of a quasi-continuum of transitions between excited quantum dot states that are enhanced by the cavity mode. Our model fully explains photon correlation measurements demonstrating that photons emitted at the cavity frequency are essentially uncorrelated with each other even though they are generated by a single quantum dot., Comment: 5 pages, 4 figures

Published

2009

88. Fermionized photons in an array of driven dissipative nonlinear cavities

Author

Carusotto, Iacopo, Gerace, Dario, Tureci, Hakan, De Liberato, Simone, Ciuti, Cristiano, and Imamoglu, Atac

Subjects

Condensed Matter - Other Condensed Matter, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We theoretically investigate the optical response of a one-dimensional array of strongly nonlinear optical microcavities. When the optical nonlinearity is much larger than both losses and inter-cavity tunnel coupling, the non-equilibrium steady state of the system is reminiscent of a strongly correlated Tonks-Girardeau gas of impenetrable bosons. Signatures of strong correlations are identified in the absorption spectrum of the system, as well as in the intensity correlations of the emitted light. Possible experimental implementations in state-of-the-art solid-state devices are discussed.

Published

2008

89. Cavity-QED based on collective magnetic dipole coupling: spin ensembles as hybrid two-level systems

Author

Imamoglu, Atac

Subjects

Quantum Physics

Abstract

We analyze the magnetic dipole coupling of an ensemble of spins to a superconducting microwave stripline structure, incorporating a Josephson junction based transmon qubit. We show that this system is described by an embedded Jaynes-Cummings model: in the strong coupling regime, collective spin-wave excitations of the ensemble of electrons pick up the nonlinearity of the cavity mode, such that the two lowest eigenstates of the coupled spin-wave + microwave-cavity + Josephson-junction system define a hybrid two-level system. The proposal described here enables the use of spin ensembles as qubits which can be coherently manipulated and coupled using the same nonlinear-cavity. Possibility of strong-coupling cavity-QED with magnetic-dipole transitions opens up the possibility of extending previously proposed quantum information processing protocols to spins in silicon or graphene, without the need for single-electron confinement., Comment: 4 pages

Published

2008

90. Quantum dot spectroscopy using cavity QED

Author

Winger, Martin, Badolato, Antonio, Hennessy, Kevin, Hu, Evelyn, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Cavity quantum electrodynamics has attracted substantial interest, both due to its potential role in the field of quantum information processing and as a testbed for basic experiments in quantum mechanics. Here, we show how cavity quantum electrodynamics using a tunable photonic crystal nanocavity in the strong coupling regime can be used for single quantum dot spectroscopy. From the distinctive avoided crossings observed in the strongly coupled system we can identify the neutral and single positively charged exciton as well as the biexciton transitions. Moreover we are able to investigate the fine structure of those transitions and to identify a novel cavity mediated mixing of bright and dark exciton states, where the hyperfine interactions with lattice nuclei presumably play a key role. These results are enabled by a deterministic coupling scheme which allowed us to achieve unprecedented coupling strengths in excess of 0.15 meV., Comment: 5 pages, 3 figures

Published

2008

91. All-Optical Manipulation of Electron Spins in Carbon-Nanotube Quantum Dots

Author

Galland, Christophe and Imamoglu, Atac

Subjects

Condensed Matter - Other Condensed Matter

Abstract

We demonstrate theoretically that it is possible to manipulate electron or hole spins all optically in semiconducting carbon nanotubes. The scheme that we propose is based on the spin-orbit interaction that was recently measured experimentally; we show that this interaction, together with an external magnetic field, can be used to achieve optical electron-spin state preparation with a fidelity exceeding 99%. Our results also imply that it is possible to implement coherent spin rotation and measurement using laser fields linearly polarized along the nanotube axis, as well as to convert spin qubits into time-bin photonic qubits. We expect that our findings will open up new avenues for exploring spin physics in one-dimensional systems.

Published

2008

92. Non-Markovian decoherence of localized nanotube excitons by acoustic phonons

Author

Galland, Christophe, Högele, Alexander, Türeci, Hakan E., and Imamoğlu, Ataç

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We demonstrate that electron-phonon interaction in quantum dots embedded in one-dimensional systems leads to pronounced, non-Markovian decoherence of optical transitions. The experiments we present focus on the lineshape of photoluminescence from low-temperature axially localized carbon nanotube excitons. The independent boson model that we use to model the phonon interactions reproduces with very high accuracy the broad and asymmetric emission lines and the weak red-detuned radial breathing mode replicas observed in the experiments. The intrinsic phonon-induced pure-dephasing of the zero-phonon line is two orders of magnitude larger than the lifetime broadening and is a hallmark of the reduced dimensionality of the phonon bath. The non-Markovian nature of this decoherence mechanism may have adverse consequences for applications of one-dimensional systems in quantum information processing., Comment: 4 pages, 3 figures

Published

2008

93. Observation of dressed excitonic states in a single quantum dot

Author

Jundt, Gregor, Robledo, Lucio, Högele, Alexander, Fält, Stefan, and Imamoğlu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report the observation of dressed states of a quantum dot. The optically excited exciton and biexciton states of the quantum dot are coupled by a strong laser field and the resulting spectral signatures are measured using differential transmission of a probe field. We demonstrate that the anisotropic electron-hole exchange interaction induced splitting between the x- and y-polarized excitonic states can be completely erased by using the AC-Stark effect induced by the coupling field, without causing any appreciable broadening of the spectral lines. We also show that by varying the polarization and strength of a resonant coupling field, we can effectively change the polarization-axis of the quantum dot.

Published

2007

94. Strong Electron-Hole Exchange in Coherently Coupled Quantum Dots

Author

Falt, Stefan, Atature, Mete, Tureci, Hakan E., Zhao, Yong, Badolato, Antonio, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We have investigated few-body states in vertically stacked quantum dots. Due to small inter-dot tunneling rate, the coupling in our system is in a previously unexplored regime where electron-hole exchange is the dominant spin interaction. By tuning the gate bias, we are able to turn this coupling off and study a complementary regime where total electron spin is a good quantum number. The use of differential transmission allows us to obtain unambiguous signatures of the interplay between electron and hole spin interactions. Small tunnel coupling also enables us to demonstrate all-optical charge sensing, where conditional exciton energy shift in one dot identifies the charging state of the coupled partner., Comment: 10 pages, 3 figures

Published

2007

95. Photon Antibunching in the Photoluminescence Spectra of a Single Carbon Nanotube

Author

Högele, Alexander, Galland, Christophe, Winger, Martin, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report the first observation of photon antibunching in the photoluminescence from single carbon nanotubes. The emergence of a fast luminescence decay component under strong optical excitation indicates that Auger processes are partially responsible for inhibiting two-photon generation. Additionally, the presence of exciton localization at low temperatures ensures that nanotubes emit photons predominantly one by one. The fact that multiphoton emission probability can be smaller than 5% suggests that carbon nanotubes could be used as a source of single photons for applications in quantum cryptography., Comment: content as published

Published

2007

96. Optical investigations of quantum-dot spin dynamics

Author

Dreiser, Jan, Atature, Mete, Galland, Christophe, Muller, Tina, Badolato, Antonio, and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We have performed all-optical measurements of spin relaxation in single self-assembled InAs/GaAs quantum dots (QD) as a function of static external electric and magnetic fields. To study QD spin dynamics we measure the degree of resonant absorption which results from a competition between optical spin pumping induced by the resonant laser field and spin relaxation induced by reservoirs. Fundamental interactions that determine spin dynamics in QDs are hyperfine coupling to QD nuclear spin ensembles, spin-phonon coupling and exchange-type interactions with a nearby Fermi sea of electrons. We show that the strength of spin relaxation generated by the three fundamental interactions can be changed by up to five orders of magnitude upon varying the applied electric and magnetic fields. We find that the strength of optical spin pumping that we use to study the spin relaxation is determined predominantly by hyperfine-induced mixing of single-electron spin states at low magnetic fields and heavy-light hole mixing at high magnetic fields. Our measurements allow us to determine the rms value of the hyperfine (Overhauser) field to be ~15 mTesla with an electron g-factor of g_e=0.6 and a hole mixing strength of |epsilon|^2 = 0.0005., Comment: submitted to Physical Review B, 19 Pages in RevTeX4 format

Published

2007

97. Electromagnetically Induced Transparency in optically trapped rubidium atoms

Author

Kaltenhäuser, Bernd, Kübler, Harald, Chromik, Andreas, Stuhler, Jürgen, Pfau, Tilman, and Imamoglu, Atac

Subjects

Quantum Physics

Abstract

We demonstrate electromagnetically induced transparency (EIT) in a sample of rubidium atoms, trapped in an optical dipole trap. Mixing a small amount of $\sigma^-$-polarized light to the weak $\sigma^+$-polarized probe pulses, we are able to measure the absorptive and dispersive properties of the atomic medium at the same time. Features as small as 4 kHz have been detected on an absorption line with 20 MHz line width., Comment: 5 pages, 8 figures

Published

2007

98. Quantum optical interface for gate-controlled spintronic devices

Author

Engel, Hans-Andreas, Taylor, Jacob M., Lukin, Mikhail D., and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We describe an opto-electronic structure in which charge and spin degrees of freedom in electrical gate-defined quantum dots can be coherently coupled to light. This is achieved via electron-electron interaction or via electron tunneling into a proximal self-assembled quantum dot. We illustrate potential applications of this approach by considering several quantum control techniques, including optical read-out of gate-controlled semiconductor quantum bits and controlled generation of entangled photon-spin pairs., Comment: 5 pages, 2 figures

Published

2006

99. Observation of Faraday rotation from a single confined spin

Author

Atature, Mete, Dreiser, Jan, Badolato, Antonio, and Imamoglu, Atac

Subjects

Quantum Physics

Abstract

Ability to read-out the state of a single confined spin lies at the heart of solid-state quantum information processing. While all-optical spin measurements using Faraday rotation has been successfully implemented in ensembles of semiconductor spins, read-out of a single semiconductor spin has only been achieved using transport measurements based on spin-charge conversion. Here, we demonstrate an all-optical dispersive measurement of the spin-state of a single electron trapped in a semiconductor quantum dot. We obtain information on the spin state through conditional Faraday rotation of a spectrally detuned optical field, induced by the polarization- and spin-selective trion (charged quantum dot) transitions. To assess the sensitivity of the technique, we use an independent resonant laser for spin-state preparation. An all-optical dispersive measurement on single spins has the important advantage of channeling the measurement back-action onto a conjugate observable, thereby allowing for repetitive or continuous quantum nondemolition (QND) read-out of the spin-state. We infer from our results that there are of order unity back-action induced spin-flip Raman scattering events within our measurement timescale. Therefore, straightforward improvements such as the use of a solid-immersion lens and higher efficiency detectors would allow for back-action evading spin measurements, without the need for a cavity.

Published

2006

100. Ultra-long distance interaction between spin qubits

Author

Burkard, Guido and Imamoglu, Atac

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We describe a method for implementing deterministic quantum gates between two spin qubits separated by centimeters. Qubits defined by the singlet and triplet states of two exchange coupled quantum dots have recently been shown to possess long coherence times. When the effective nuclear fields in the two asymmetric quantum dots are different, total spin will no longer be a good quantum number and there will be a large electric dipole coupling between the two qubit states. We show that when such a double-quantum-dot qubit is embedded in a superconducting microstrip cavity, the strong coupling regime of cavity quantum electrodynamics lies within reach. Virtual photons in a common cavity mode could mediate coherent interactions between two distant qubits embedded in the same structure; the range of this two-qubit interaction is determined by the wavelength of the microwave transition., Comment: 5 pages, 2 figures; final version v2 (minor changes)

Published

2006