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1,318 results on '"Walmsley, Ian A."'

951. The formation of ultracold rubidium molecules using ultrafast photoassociation

Author

McCabe, David J. and Walmsley, Ian A.

Subjects
539.6, Physical Sciences, Physics, Atomic and laser physics, ultrafast, ultracold, pump-probe, coherent control, quantum control, photoassociation, spectroscopy, femtochemistry
Abstract

The establishment of robust laser-cooling techniques for the formation of ultracold atoms has provided a test-bed for low-temperature science, with scattering events changing character from incoherent thermal interactions to coherent quantum mechanical events. A natural extension is the pursuit of ultracold molecules in prescribed low-energy internal states. Atomic cooling techniques, however, do not generalize to the molecular regime due to the complex energy-level structure afforded by its extra degrees of motion. An indirect approach to ultracold molecule formation - photoassociation using ultrafast laser pulses - is the focus of this thesis. A broadband field associates atom pairs into a localized molecular wavepacket that evolves within the attractive excited-state potential. A suitably timed dump pulse may thus be applied to stabilize population into deeply bound ground vibrational states. This strategy may be generalized to any species whose spectroscopy matches the pulse spectrum, and offers a coherent population transfer scheme that does not require precise knowledge of the system. This thesis presents experiments using high-energy photoassociation pulses applied to ultracold rubidium atoms. The pulses quench the background ground-state molecular population but form bound dimers within the excited state. A pump-probe experiment was designed to chart the excited-state dynamics; however, the oscillations predicted by theoretical calculations were not evident in the molecular signal. The nature of the dynamics is expected to be strongly dependent on the initial state of the atom pairs addressed by the ultrafast pulse: a bound molecular population provides an additional candidate to free atoms. A spectroscopic measurement characterizes these bound molecules and identifies their formation mechanism. A subsequent experiment provides evidence that the predominant contributor to the pump-probe signal is the unbound initial population. The consequences with regard to both the observation of excited-state dynamics and the subsequent application of a dump pulse are discussed.

Published
2010

954. High-resolution interferometric diagnostics for ultrashort pulses

Author

Austin, Dane R. and Walmsley, Ian A.

Subjects
535, Atomic and laser physics, Physics, interferometry, ultrashort pulses, ultrafast optics, high-harmonic generation, nonlinear optics, metrology, phase retrieval
Abstract

I present several new methods for the characterisation of ultrashort pulses using interferometry. A generalisation of the concatenation algorithm for spectral shearing interferometry enables interferograms taken at multiple shears to be combined. This improves the precision of the reconstructed phase in the presence of detector noise, and enables the relative phase between disjoint spectral components to be obtained without decreasing the spectral resolution. The algorithm is applied to experimental data from two different implementations of spectral shearing interferometry for ultrashort optical pulses. In one, the shears are acquired sequentially, and in the other they are acquired simultaneously. I develop a form of spatio-temporal ultrashort pulse characterisation which performs both spatial and spectral shearing interferometry simultaneously. It requires a similar geometrical setup to common implementations of spectral phase interferometry for direct electric-field reconstruction, but provides complete amplitude and phase characterisation in time and one spatial dimension. I develop the theory of lateral shearing interferometry for spectrally resolved wavefront sensing of extended ultraviolet and soft x-ray pulses generated using high-harmonic generation. A comprehensive set of wavefront measurements of harmonics 13-25 in Krypton show good agreement with theory, validating the technique. I propose and numerically demonstrate quantum-path interferometry mediated by a weak control field for high harmonic generation. This is a general technique for measuring the amplitude and relative phases of each contributing quantum path. The control field perturbatively modulates the phase of each path. The differing sensitivity of each path to the parameters of the control field allows their contributions to be distinguished from one another.

Published
2010

955. Coherent control of decoherence

Author

Branderhorst, Matthijs Pieter Arie and Walmsley, Ian A.

Subjects
530.12, Control theory, Coherence (Nuclear physics), Laser spectroscopy
Published
2008

956. Dynamics of Feshbach molecule production

Author

Hanna, Thomas Mark and Walmsley, Ian

Subjects
538, Atomic and laser physics, Feshbach molecules, Bose-Einstein condensate, cold gases
Abstract

The variation of a magnetic field in the vicinity of a zero-energy resonance allows highly vibrationally excited molecules (‘Feshbach molecules’) to be produced from an ultracold atomic gas. In this thesis, we study the dynamics of this process. We begin by studying the dissociation of Feshbach molecules, showing that in the limit of a sudden jump the shape of the spectrum of dissociated atoms can act as a probe of the zero-energy resonance. For some resonances, such jumps are within reach of current experiments. We also study the intermediate region between sudden jumps and asymptotically wide, linear ramps. It is shown from a precise derivation how the latter limit leads to a universal spectrum with a shape independent of the implementation of the two-body physics, provided that the near-resonant scattering properties are correctly modelled. We then turn to the dynamics of Feshbach molecule production from thermal and condensed gases. Our microscopic quantum dynamics approach includes the exact twobody evolution as an input to the many-body calculations. We show that in the long-time limit, and the Markov limit for the interactions, the non-Markovian Boltzmann equation (NMBE) we derive for the one-body density matrix reduces to the normal Boltzmann equation. In the limit of short times and small depletion of the atomic gas, the molecule production efficiency can be calculated by thermally averaging the two-body transition probability density. This thermal averaging technique is applied to studies of the formation of Feshbach molecules using a magnetic field modulation that is near-resonant with the molecular bound state energy. The continuum is shown to have a significant effect on both the dynamics and efficiency of this process. We examine the dependence of the molecule production efficiency on the duration, amplitude and frequency of the modulation, as well as the temperature and density of the gas. This method of producing molecules is effective for a wide range of bound state energies, but requires sufficient variation of the two-body energy levels with magnetic field. Lastly, we implement the NMBE for the case of a fast linear ramp across a Feshbach resonance. The solution of this equation is made feasible by including a large part of the required computation in the kernel, which is calculated in advance. The NMBE allows predictions of the molecule production efficiency which go beyond the thermal averaging technique by accounting for the depletion and rethermalisation of the continuum. In the limit of small depletions, the two approaches give the same results. As the depletion increases, the two approaches differ due to many-body effects limiting the maximum possible molecule production efficiency. We have observed this in our simulations by considering higher-density gases. We have therefore shown the suitability and practicability of this beyond mean-field approach for application to further problems in the production of Feshbach molecules from ultracold gases.

Published
2008

957. Strong correlations in ultracold atomic gases

Author

Nunnenkamp, Andreas, Burnett, Keith, and Walmsley, Ian

Subjects
531.16, Physical Sciences, Physics, Atomic and laser physics, Theoretical physics, ultracold bosons, optical lattices, macroscopic superposition states, quantum information science, entanglement, strongly correlated systems
Abstract

In this thesis we investigate strongly-correlated states of ultracold bosonic atoms in rotating ring lattices and arrays of double-well potentials. In the first part of the thesis, we study the tunneling dynamics of ultracold bosons in double-well potentials. In the non-interacting limit single-particle transitions dominate, while in the interaction-dominated regime correlated tunneling of all particles prevails. At intermediate times of the many-particle flopping process correlated states occur, but the timescales of these processes increase dramatically with the number of particles. Using an array of double-well potentials, a large number of such few-particle superposition states can be produced in parallel. In the second part of the thesis, we study the effects of rotation on ultracold bosons confined to one-dimensional ring lattices. We find that at commensurate filling there exists a critical rotation frequency, at which the ground state of the weakly-interacting gas is fragmented into a macroscopic superposition of different quasi-momentum states. We demonstrate that the generation of such superposition states using slightly non-uniform ring lattices has several practical advantages. Moreover, we show that different quasi-momentum states can be distinguished in time-of-flight absorption imaging and propose to probe correlations via the many-body oscillations induced by a sudden change in the rotation frequency. Finally, we compare these macroscopic superposition states to those occurring in superconducting quantum interference devices. In the third part of the thesis, we demonstrate the creation of entangled states with ultracold bosonic atoms by dynamical manipulation of the shape of the lattice potential. To this end, we consider an optical superlattice that allows both the splitting of each site into a double-well potential and the variation of the height of the potential barrier between the sites. We show how to use this array of double-well potentials to perform entangling operations between neighboring qubits encoded on the Zeeman levels of the atoms. As one possible application, we present a method of realizing a resource state for measurement-based quantum computation via Bell-pair measurements. In the final part of the thesis, we study ultracold bosons on a two-dimensional square lattice in the presence of an effective magnetic field and point out a couple of features this system has in common with ultracold bosons in one-dimensional rotating ring lattices.

Published
2008

958. Spectral interferometry for the complete characterisation of near infrared femtosecond and extreme ultraviolet attosecond pulses

Author

Wyatt, Adam Stacey and Walmsley, Ian A.

Subjects
535, Physical Sciences, Physics, Atomic and laser physics, spectral interferometry, spectral phase interferometry for direct electric-field reconstruction, high harmonic generation, spatially encoded arrangement, attosecond, femtosecond, space-time coupling
Abstract

This thesis describes methods for using spectral interferometry for the complete space-time characterisation of few-cycle near-infrared femtosecond pulses and extreme ultraviolet (XUV) attosecond pulses produced via high harmonic generation (HHG). Few-cycle pulses tend to exhibit one or more of the following: (1) an octave-spanning bandwidth, (2) a highly modulated spectrum and (3) space-time coupling. These characteristics, coupled with the desire to measure them in a single-shot (to characterise shot-to-shot fluctuations) and in real-time (for online optimisation and control) causes problems for conventional characterisation techniques. The first half of this thesis describes a method, based on a spatially encoded arrangement for spectral phase interferometry for direct electric-field reconstruction (SEA-SPIDER). SEA-SPIDER is demonstrated for sub-10fs pulses with a central wavelength near 800nm, a bandwidth over 350nm, and a pulse energy of several nano-Joules. In addition, the pulses exhibit a modulated spectrum and space-time coupling. The spatially-dependent temporal intensity of the pulse is reconstructed and compared to other techniques: interferometric frequency-resolved optical gating (IFROG) and spectral phase interferometry for direct electric field reconstruction (SPIDER). SEA-SPIDER will prove useful in both femtoscience, which requires accurate knowledge of the space-time character of few-cycle pulses, and in HHG, which requires the precise knowledge of the driving pulse for seeding into simulations and controlling the generation process itself. Pulses arising from HHG are known to exhibit significant space-time coupling. The second half of this thesis describes how spectral interferometry may be performed to obtain the complete space-time nature of these fields via the use of lateral shearing interferometry. Finally, it is shown, via numerical simulations, how to extend the SPIDER technique for temporal characterisation of XUV pulses from HHG by driving the process with two spectrally-sheared driving pulses. Different experimental configurations and their applicability to different laser systems are discussed. This method recovers the space-time nature of the harmonics in a single shot, thus reducing the stability constraint currently required for photoelectron based techniques and may serve as a complimentary method for studying interactions of XUV attosecond pulses with matter.

Published
2007

959. Generation of heralded single photons in pure quantum states

Author

Mosley, Peter James and Walmsley, Ian A.

Subjects
531.16, Atomic and laser physics, Quantum information processing, Quantum physics, photon, parametric downconversion, single photon source, pure state, interference, spectral engineering
Abstract

Single photons - discrete wavepackets of light - are one of the most fundamental entities in physics. In recent years, the ability to consistently create and manipulate both single photons and pairs of photons has facilitated everything from tests of quantum theory to the implementation of quantum-enhanced precision measurements. These activities all fall within the scope of the rapidly-growing field of quantum information - the exploitation of the properties of quantum states (and specifically their capability to exist in superpositions) to accomplish tasks that would not be possible with classical objects. One stated goal of research in quantum information is to build a device consisting of a network of quantum logic gates that can evaluate quantum algorithms. The photonic implementation of individual logic gates has already been demonstrated. However, partly due to standard methods of preparing single photons, current schemes have severe limitations in terms of scaling up from a single logic gate to multiple concatenated operations. Until now it has not been proven that single photons can be generated in pure and indistinguishable quantum states, something upon which the successful operation of optical quantum logic gates relies. This thesis presents an experimental demonstration of simultaneous generation of almost identical single photons in highly pure states from two independent sources based on parametric downconversion. This is a process of photon pair generation during the passage of a light beam through a nonlinear crystal; one photon from the resulting pair is detected to herald the other. The work herein describes, refines, and implements a technique that minimises the strong quantum correlations usually present within each pair by spectral engineering of the source. This allows the heralded single photons to be in pure states, a property that is confirmed by observing a high-visibility two-photon interference effect without spectral filtering.

Published
2007

960. Quantum-enhanced stimulated emission detection for label-free microscopy.

Author

Triginer Garces, Gil, Chrzanowski, Helen M., Daryanoosh, Shakib, Thiel, Valerian, Marchant, Anna L., Patel, Raj B., Humphreys, Peter C., Datta, Animesh, and Walmsley, Ian A.

Subjects
*STIMULATED emission, *NONLINEAR optical techniques, *SQUEEZED light, *LABELS, *QUANTUM fluctuations, *MICROSCOPY, *PUMP probe spectroscopy
Abstract

Nonlinear optical microscopy techniques have emerged as a set of successful tools for biological imaging. Stimulated emission microscopy belongs to a small subset of pump–probe techniques, which can image non-fluorescent samples without requiring fluorescent labeling. However, its sensitivity has been shown to be ultimately limited by the quantum fluctuations in the probe beam. We propose and experimentally implement sub-shot-noise limited stimulated emission microscopy by preparing the probe pulse in an intensity-squeezed state. This technique paves the way for imaging delicate biological samples that have no detectable fluorescence with sensitivity beyond standard quantum fluctuations. [ABSTRACT FROM AUTHOR]

Published
2020
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961. A hybrid quantum memory-enabled network at room temperature.

Author

Xiao-Ling Pang, Ai-Lin Yang, Jian-Peng Dou, Hang Li, Chao-Ni Zhang, Poem, Eilon, Saunders, Dylan J., Hao Tang, Joshua Nunn, Walmsley, Ian A., and Xian-Min Jin

Subjects
*QUANTUM noise, *QUANTUM computing, *BELL'S theorem, *SATURATION vapor pressure, *PHOTON echoes
Abstract

The article present the first hybrid quantum memory-enabled network by demonstrating the interconnection and simultaneous operation of two types of quantum memory including an atomic ensemble-based memory and an all-optical Loop memory. It observes a well-preserved quantum correlation and a violation of Cauchy-Schwarz inequality by interfacing the quantum memories at room temperature.

Published
2020
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962. Book reviews.

Author

Walmsley, Ian

Subjects
QUANTUM Optics (Book)
Abstract

Reviews the book `Quantum Optics,' by Marlan O. Scully and M. Suhail Zubairy.

Published
1999

963. Laser Induced Nuclear Reactions

Author

Ewald, Friederike, Schwoerer, Heinrich, Magill, Joseph, Galy, Jean, Schenkel, Roland, Sauerbrey, Roland, Rhodes, W. T., editor, Krausz, Ferenc, editor, Korn, Georg, editor, Corkum, Paul, editor, and Walmsley, Ian A., editor

Published
2004
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966. Time-Resolved Inner Shell Spectroscopy with Sub-fs EUV Pulses

Author

Drescher, M., Hentschel, M., Kienberger, R., Uiberacker, M., Yakovlev, V., Scrinzi, A., Westerwalbesloh, Th., Kleineberg, U., Heinzmann, U., Krausz, F., Rhodes, W. T., editor, Krausz, Ferenc, editor, Korn, Georg, editor, Corkum, Paul, editor, and Walmsley, Ian A., editor

Published
2004
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991. Towards Attosecond Half-Cycle Pulses

Author

Persson, Emil, Puschkarski, Severin, Tong, Xiao-Min, Burgdörfer, Joachim, Rhodes, W. T., editor, Krausz, Ferenc, editor, Korn, Georg, editor, Corkum, Paul, editor, and Walmsley, Ian A., editor

Published
2004
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