Your search keyword '"Kundys, Dmytro"' showing total 15 results

1. Boson Sampling on a Photonic Chip

Author

Spring, Justin B., Metcalf, Benjamin J., Humphreys, Peter C., Kolthammer, W. Steven, Jin, Xian-Min, Barbieri, Marco, Datta, Animesh, Thomas-Peter, Nicholas, Langford, Nathan K., Kundys, Dmytro, Gates, James C., Smith, Brian J., Smith, Peter G. R., and Walmsley, Ian A.

Published

2013

2. Single-pulse multiphoton fabrication of high aspect ratio structures with sub-micron features using vortex beams

Author

Mills, Benjamin, Kundys, Dmytro, Farsari, Maria, Mailis, Sakellaris, and Eason, Robert W.

Published

2012

3. Numerical Study of Reconfigurable Mid‐IR Single Photon Sources Based on Functional Ferroelectrics.

Author

Kundys, Dmytro, Graffitti, Francesco, McCracken, Richard A., Fedrizzi, Alessandro, and Kundys, Bohdan

Abstract

The future of quantum photonic technology depends on the realization of efficient sources of single photons, the ideal carriers of quantum information. Parametric downconversion (PDC) is a promising route to create highly coherent, spectrally pure single photons for quantum photonics using versatile group velocity matching (GVM) and tailored nonlinearities. However, the functionality to actively control the poling period of nonlinear crystals used in PDC is currently missing, yet would enable to dynamically modify the wavelength of single photons produced in the PDC process. Herein, a detailed GVM study is presented for functional PMN‐0.38PT material which can be dynamically repolled at ambient conditions with fields as low as 0.4 kV mm−1. The study reveals phase‐matching conditions for spectrally pure single photon creation at 5–6 µm. Further, a practical approach is proposed for on‐flight wavelength switching of the created single photons. The reported reconfigurable functionality benefits a wide range of emerging quantum‐enhanced applications in the mid‐IR spectral region where the choice of single photon sources is currently limited. [ABSTRACT FROM AUTHOR]

Published

2020

4. Nonlinear Light Mixing by Graphene Plasmons.

Author

Kundys, Dmytro, Van Duppen, Ben, Marshall, Owen P., Rodriguez, Francisco, Torre, Iacopo, Tomadin, Andrea, Polini, Marco, and Grigorenko, Alexander N.

Subjects

*GRAPHENE, *MIXING, *PLASMONS (Physics), *NONLINEAR systems, *PHYSICS experiments

Abstract

Graphene is known to possess strong optical nonlinearity which turned out to be suitable for creation of efficient saturable absorbers in mode locked fiber lasers. Nonlinear response of graphene can be further enhanced by the presence of graphene plasmons. Here, we report a novel nonlinear effect observed in nanostructured graphene which comes about due to excitation of graphene plasmons. We experimentally detect and theoretically explain enhanced mixing of near-infrared and mid-infrared light in arrays of graphene nanoribbons. Strong compression of light by graphene plasmons implies that the described effect of light mixing is nonlocal in nature and orders of magnitude larger than the conventional local graphene nonlinearity. Both second and third order nonlinear effects were observed in our experiments with the recalculated third-order nonlinearity coefficient reaching values of 4.5 x 10-6 esu. The suggested effect could be used in variety of applications including nonlinear light modulators, light multiplexers, light logic, and sensing devices. [ABSTRACT FROM AUTHOR]

Published

2018

5. A study of the optical and polarisation properties of InGaN/GaN multiple quantum wells grown on a -plane and m -plane GaN substrates.

Author

Kundys, Dmytro, Sutherland, Danny, Davies, Matthew J., Oehler, Fabrice, Griffiths, James, Dawson, Philip, Kappers, Menno J., Humphreys, Colin J., Schulz, Stefan, Tang, Fengzai, and Oliver, Rachel A.

Subjects

*OPTICAL properties of indium gallium nitride, *QUANTUM wells, *TIME-resolved spectroscopy

Abstract

We report on a comparative study of the low temperature emission and polarisation properties of InGaN/GaN quantum wells grown on nonpolar ()a-plane and ()m-plane free-standing bulk GaN substrates where the In content varied from 0.14 to 0.28 in them-plane series and 0.08 to 0.21 for thea-plane series. The low temperature photoluminescence spectra from both sets of samples are broad with full width at half maximum height increasing from 81 to 330 meV as the In fraction increases. Photoluminescence excitation spectroscopy indicates that the recombination mainly involves strongly localised carriers. At 10 K the degree of linear polarisation of thea-plane samples is much smaller than of them-plane counterparts and also varies across the spectrum. From polarisation-resolved photoluminescence excitation spectroscopy we measured the energy splitting between the lowest valence sub-bands to lie in the range of 23–54 meV for thea- andm-plane samples in which we could observe distinct exciton features. Thus the thermal occupation of a higher valence sub-band cannot be responsible for the reduction of the degree of linear polarisation at 10 K. Time-resolved spectroscopy indicates that ina-plane samples there is an extra emission component which is at least partly responsible for the reduction in the degree of linear polarisation. [ABSTRACT FROM PUBLISHER]

Published

2016

6. Optical studies of non-polar m-plane (.

Author

Sutherland, Danny, Zhu, Tongtong, Griffiths, James T., Tang, Fengzai, Dawson, Phil, Kundys, Dmytro, Oehler, Fabrice, Kappers, Menno J., Humphreys, Colin J., and Oliver, Rachel A.

Subjects

QUANTUM wells, OPTICAL properties, PHOTOLUMINESCENCE, LOW temperatures, TIME-resolved spectroscopy, SCANNING transmission electron microscopy

Abstract

We report on the optical properties of non-polar m-plane InGaN/GaN multi-quantum wells (MQWs) grown on ammonothermal bulk GaN substrates. The low temperature continuous wave (CW) photoluminescence spectra are broad with a characteristic low energy tail. The majority of the emission bands decay with a time constant ~300 ps, but detailed photoluminescence time decay and time resolved spectroscopy measurements revealed the existence of a distinct slowly decaying emission band. This slowly decaying component is responsible for the low energy tails observed in the CW spectra. Scanning electron microscopy-cathodo­luminescence (SEM-CL) studies show that the low energy emission band originates from regions across step-bunches, which are associated to the GaN substrate miscut. Subsequent scanning transmission electron microscopy imaging demonstrates that semi-polar QWs had formed continuous layers on the step bunches between the m-plane QWs and were responsible for the slower decaying, low energy emission band. Thus we assign the asymmetric low energy emission tails observed in photoluminescence studies to the formation of semi-polar facet QWs across the step bunches associated with the GaN miscut. [ABSTRACT FROM AUTHOR]

Published

2015

7. Quantum teleportation on a photonic chip.

Author

Metcalf, Benjamin J., Spring, Justin B., Humphreys, Peter C., Thomas-Peter, Nicholas, Barbieri, Marco, Kolthammer, W. Steven, Jin, Xian-Min, Langford, Nathan K., Kundys, Dmytro, Gates, James C., Smith, Brian J., Smith, Peter G. R., and Walmsley, Ian A.

Subjects

QUANTUM teleportation, QUANTUM theory, QUANTUM communication, OPTICS, LIGHTING

Abstract

Quantum teleportation is a fundamental concept in quantum physics that now finds important applications at the heart of quantum technology, including quantum relays, quantum repeaters and linear optics quantum computing. Photonic implementations have largely focused on achieving long-distance teleportation for decoherence-free quantum communication. Teleportation also plays a vital role in photonic quantum computing, for which large linear optical networks will probably require an integrated architecture. Here, we report a fully integrated implementation of quantum teleportation in which all key parts of the circuit-entangled state preparation, Bell-state analysis and tomographic state measurement-are performed on a reconfigurable photonic chip. We also show that a novel element-wise characterization method is critical to the mitigation of component errors, a key technique that will become increasingly important as integrated circuits reach the higher complexities necessary for quantum enhanced operation. [ABSTRACT FROM AUTHOR]

Published

2014

8. Use of Cross-Couplers to Decrease Size of UV Written Photonic Circuits.

Author

Kundys, Dmytro O., Gates, James C., Dasgupta, Sonali, Gawith, Corin B. E., and Smith, Peter G. R.

Published

2009

9. Strong coupling of diffraction coupled plasmons and optical waveguide modes in gold stripe-dielectric nanostructures at telecom wavelengths.

Author

Thomas, Philip A., Auton, Gregory H., Kundys, Dmytro, Grigorenko, Alexander N., and Kravets, Vasyl G.

Abstract

We propose a hybrid plasmonic device consisting of a planar dielectric waveguide covering a gold nanostripe array fabricated on a gold film and investigate its guiding properties at telecom wavelengths. The fundamental modes of a hybrid device and their dependence on the key geometric parameters are studied. A communication length of 250 μm was achieved for both the TM and TE guided modes at telecom wavelengths. Due to the difference between the TM and TE light propagation associated with the diffractive plasmon excitation, our waveguides provide polarization separation. Our results suggest a practical way of fabricating metal-nanostripes-dielectric waveguides that can be used as essential elements in optoelectronic circuits. [ABSTRACT FROM AUTHOR]

Published

2017

10. Multiphoton quantum interference in a multiport integrated photonic device.

Author

Metcalf, Benjamin J., Thomas-Peter, Nicholas, Spring, Justin B., Kundys, Dmytro, Broome, Matthew A., Humphreys, Peter C., Jin, Xian-Min, Barbieri, Marco, Steven Kolthammer, W., Gates, James C., Smith, Brian J., Langford, Nathan K., Smith, Peter G.R., and Walmsley, Ian A.

Abstract

Increasing the complexity of quantum photonic devices is essential for many optical information processing applications to reach a regime beyond what can be classically simulated, and integrated photonics has emerged as a leading platform for achieving this. Here we demonstrate three-photon quantum operation of an integrated device containing three coupled interferometers, eight spatial modes and many classical and nonclassical interferences. This represents a critical advance over previous complexities and the first on-chip nonclassical interference with more than two photonic inputs. We introduce a new scheme to verify quantum behaviour, using classically characterised device elements and hierarchies of photon correlation functions. We accurately predict the device's quantum behaviour and show operation inconsistent with both classical and bi-separable quantum models. Such methods for verifying multiphoton quantum behaviour are vital for achieving increased circuit complexity. Our experiment paves the way for the next generation of integrated photonic quantum simulation and computing devices. [ABSTRACT FROM AUTHOR]

Published

2013

11. Experimental test of local observer independence.

Author

Proietti, Massimiliano, Pickston, Alexander, Graffitti, Francesco, Barrow, Peter, Kundys, Dmytro, Branciard, Cyril, Ringbauer, Martin, and Fedrizzi, Alessandro

Published

2019

12. Measurement-Device-Independent Verification of Quantum Channels.

Author

Graffitti, Francesco, Pickston, Alexander, Barrow, Peter, Proietti, Massimiliano, Kundys, Dmytro, Rosset, Denis, Ringbauer, Martin, and Fedrizzi, Alessandro

Subjects

*QUANTUM correlations, *QUANTUM communication, *QUANTUM noise, *NOISE

Abstract

The capability to reliably transmit and store quantum information is an essential building block for future quantum networks and processors. Gauging the ability of a communication link or quantum memory to preserve quantum correlations is therefore vital for their technological application. Here, we experimentally demonstrate a measurement-device-independent protocol for certifying that an unknown channel acts as an entanglement-preserving channel. Our results show that, even under realistic experimental conditions, including imperfect single-photon sources and the various kinds of noise--in the channel or in detection--where other verification means would fail or become inefficient, the present verification protocol is still capable of affirming the quantum behavior in a faithful manner with minimal trust on the measurement device. [ABSTRACT FROM AUTHOR]

Published

2020

13. Enhanced Multiqubit Phase Estimation in Noisy Environments by Local Encoding.

Author

Proietti, Massimiliano, Ringbauer, Martin, Graffitti, Francesco, Barrow, Peter, Pickston, Alexander, Kundys, Dmytro, Cavalcanti, Daniel, Aolita, Leandro, Chaves, Rafael, and Fedrizzi, Alessandro

Subjects

*ERROR correction (Information theory), *ENCODING, *QUANTUM coherence, *ECOLOGY

Abstract

The first generation of multiqubit quantum technologies will consist of noisy, intermediate-scale devices for which active error correction remains out of reach. To exploit such devices, it is thus imperative to use passive error protection that meets a careful trade-off between noise protection and resource overhead. Here, we experimentally demonstrate that single-qubit encoding can significantly enhance the robustness of entanglement and coherence of four-qubit graph states against local noise with a preferred direction. In particular, we explicitly show that local encoding provides a significant practical advantage for phase estimation in noisy environments. This demonstrates the efficacy of local unitary encoding under realistic conditions, with potential applications in multiqubit quantum technologies for metrology, multipartite secrecy, and error correction. [ABSTRACT FROM AUTHOR]

Published

2019

14. Towards combined quantum bit detection and spatial tracking using an arrayed single-photon sensor.

Author

Donaldson R, Kundys D, Maccarone A, Henderson R, Buller GS, and Fedrizzi A

Abstract

Experimental quantum key distribution through free-space channels requires accurate pointing-and-tracking to co-align telescopes for efficient transmission. The hardware requirements for the sender and receiver could be drastically reduced by combining the detection of quantum bits and spatial tracking signal using two-dimensional single-photon detector arrays. Here, we apply a two-dimensional CMOS single-photon avalanche diode detector array to measure and monitor the single-photon level interference of a free-space time-bin receiver interferometer while simultaneously tracking the spatial position of the single-photon level signal. We verify an angular field-of-view of 1.28° and demonstrate a post-processing technique to reduce background noise. The experimental results show a promising future for two-dimensional single-photon detectors in low-light level free-space communications, such as quantum communications.

Published

2021

15. Phase-controlled integrated photonic quantum circuits.

Author

Smith BJ, Kundys D, Thomas-Peter N, Smith PG, and Walmsley IA

Subjects

Computer Simulation, Computer-Aided Design, Equipment Design, Equipment Failure Analysis, Light, Models, Theoretical, Photons, Pilot Projects, Scattering, Radiation, Systems Integration, Interferometry instrumentation, Optical Devices, Refractometry instrumentation

Abstract

Scalable photonic quantum technologies are based on multiple nested interferometers. To realize this architecture, integrated optical structures are needed to ensure stable, controllable, and repeatable operation. Here we show a key proof-of-principle demonstration of an externallycontrolled photonic quantum circuit based upon UV-written waveguide technology. In particular, we present non-classical interference of photon pairs in a Mach-Zehnder interferometer constructed with X couplers in an integrated optical circuit with a thermo-optic phase shifter in one of the interferometer arms.

Published

2009