Ian Walmsley

Noise suppression via atomic absorption in a Raman quantum memory

Quantum Information and Measurement (QIM) V: Quantum Technologies, OSA Technical Digest (Optical Society of America, 2019) OSA Publishing (2019)

Authors:

Tm Hird, SE Thomas, JHD Munns, B Brecht, DJ Saunders, J Nunn, IA Walmsley, Patrick Ledingham

Abstract:

We demonstrate strong suppression of noise on the output of a Raman quantum memory.

Experimental demonstration of quantum effects in the operation of microscopic heat engines

Physical Review Letters American Physical Society 122 (2019) 110601

Authors:

J Klatzow, J Becker, Patrick Ledingham, C Weinzetl, K Kaczmarek, D Saunders, J Nunn, I Walmsley, R Uzdin, E Poem

Abstract:

The ability of the internal states of a working fluid to be in a coherent superposition is one of the basic properties of a quantum heat engine. It was recently predicted that in the regime of small engine action, this ability can enable a quantum heat engine to produce more power than any equivalent classical heat engine. It was also predicted that in the same regime, the presence of such internal coherence causes different types of quantum heat engines to become thermodynamically equivalent. Here, we use an ensemble of nitrogen vacancy centers in diamond for implementing two types of quantum heat engines, and experimentally observe both effects.

Coherent control and wave mixing in an ensemble of silicon-vacancy centers in diamond

Physical Review Letters American Physical Society 122 (2019) 063601

Authors:

Christian Weinzetl, J Goerlitz, Jonas Becker, E Poem, Ian Walmsley, J Nunn, C Becher

Abstract:

Strong light-matter interactions are critical for quantum technologies based on light, such as memories or nonlinear interactions. Solid state materials will be particularly important for such applications due to the relative ease of fabrication of components. Silicon vacancy centers (SiV−) in diamond feature especially narrow inhomogeneous spectral lines, which are rare in solid materials. Here, we demonstrate resonant coherent manipulation, stimulated Raman adiabatic passage, and strong light-matter interaction via four-wave mixing of a weak signal field in an ensemble of SiV− centers.

Spatially-resolved common-path high-order harmonic interferometry

Optics Letters Optical Society of America 43:21 (2018) 5275-5278

Authors:

MM Mang, David T Lloyd, PN Anderson, Daniel J Treacher, AS Wyatt, Simon M Hooker, Ian A Walmsley, Kevin O'Keeffe

Abstract:

Spatially resolved interference is observed between high-order harmonics generated in two longitudinally separated gas targets. High-contrast modulations in the intensity of each harmonic order up to the cutoff are observed on-axis in the far field of the source as the separation between the gas targets is increased. For low-order harmonics, additional off-axis modulations are observed, which are attributed to the interference between the contributions from the long quantum trajectories from each gas target. The inherent synchronization of this setup offers the prospect for high-stability metrology of quantum states with ultrafast temporal resolutions.

High-birefringence direct UV-written waveguides for use as heralded single-photon sources at telecommunication wavelengths.

Optics express 26:19 (2018) 24678-24686

Authors:

Matthew T Posner, T Hiemstra, Paolo L Mennea, Rex HS Bannerman, Ulrich B Hoff, Andreas Eckstein, W Steven Kolthammer, Ian A Walmsley, Devin H Smith, James C Gates, Peter GR Smith

Abstract:

Direct UV-written waveguides are fabricated in silica-on-silicon with birefringence of (4.9 ± 0.2) × 10^-4, much greater than previously reported in this platform. We show that these waveguides are suitable for the generation of heralded single photons at telecommunication wavelengths by spontaneous four-wave mixing. A pulsed pump field at 1060 nm generates pairs of photons in highly detuned, spectrally uncorrelated modes near 1550 nm and 800 nm. Waveguide-to-fiber coupling efficiencies of 78-91 % are achieved for all fields. Waveguide birefringence is controlled through dopant concentration of GeCl₄ and BCl₃ using the flame hydrolysis deposition process. The technology provides a route towards the scalability of silica-on-silicon integrated components for photonic quantum experiments.