Your search keyword '"Colquhoun, Craig D."' showing total 8 results

1. Responsive Operations for Key Services (ROKS): A Modular, Low SWaP Quantum Communications Payload

Author

Colquhoun, Craig D., Jeffrey, Hazel, Greenland, Steve, Mohapatra, Sonali, Aitken, Colin, Cebecauer, Mikulas, Crawshaw, Charlotte, Jeffrey, Kenny, Jeffreys, Toby, Karagiannakis, Philippos, McTaggart, Ahren, Stark, Caitlin, Wood, Jack, Joshi, Siddarth K., Sagar, Jaya, Hastings, Elliott, Zhang, Peide, Stefko, Milan, Lowndes, David, Rarity, John G., Sidhu, Jasminder S., Brougham, Thomas, McArthur, Duncan, Pousa, Robert G., Oi, Daniel K. L., Warden, Matthew, Johnston, Eilidh, and Leck, John

Subjects

Quantum Physics

Abstract

Quantum key distribution (QKD) is a theoretically proven future-proof secure encryption method that inherits its security from fundamental physical principles. Craft Prospect, working with a number of UK organisations, has been focused on miniaturising the technologies that enable QKD so that they may be used in smaller platforms including nanosatellites. The significant reduction of size, and therefore the cost of launching quantum communication technologies either on a dedicated platform or hosted as part of a larger optical communications will improve potential access to quantum encryption on a relatively quick timescale. The ROKS mission seeks to be among the first to send a QKD payload on a CubeSat into low Earth orbit, demonstrating the capabilities of newly developed modular quantum technologies. The ROKS payload comprises a quantum source module that supplies photons randomly in any of four linear polarisation states fed from a quantum random number generator; an acquisition, pointing, and tracking system to fine-tune alignment of the quantum source beam with an optical ground station; an imager that will detect cloud cover autonomously; and an onboard computer that controls and monitors the other modules, which manages the payload and assures the overall performance and security of the system. Each of these modules have been developed with low SWaP for CubeSats, but with interoperability in mind for other satellite form factors. We present each of the listed components, together with the initial test results from our test bench and the performance of our protoflight models prior to initial integration with the 6U CubeSat platform systems. The completed ROKS payload will be ready for flight at the end of 2022, with various modular components already being baselined for flight and integrated into third party communication missions., Comment: 13 pages with 25 figures. Presented at Small Satellite Conference: https://digitalcommons.usu.edu/smallsat/2022/all2022/163/. Any comments are welcome

Published

2022

2. Collisionally inhomogeneous Bose-Einstein condensates with a linear interaction gradient

Author

Di Carli, Andrea, Henderson, Grant, Flannigan, Stuart, Colquhoun, Craig D., Mitchell, Matthew, Oppo, Gian-Luca, Daley, Andrew J., Kuhr, Stefan, and Haller, Elmar

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We study the evolution of a collisionally inhomogeneous matter wave in a spatial gradient of the interaction strength. Starting with a Bose-Einstein condensate with weak repulsive interactions in quasi-one-dimensional geometry, we monitor the evolution of a matter wave that simultaneously extends into spatial regions with attractive and repulsive interactions. We observe the formation and the decay of soliton-like density peaks, counter-propagating self-interfering wave packets, and the creation of cascades of solitons. The matter-wave dynamics is well reproduced in numerical simulations based on the nonpolynomial Schroedinger equation with three-body loss, allowing us to better understand the underlying behaviour based on a wavelet transformation. Our analysis provides new understanding of collapse processes for solitons, and opens interesting connections to other nonlinear instabilities.

Published

2019

3. Excitation modes of bright matter-wave solitons

Author

Di Carli, Andrea, Colquhoun, Craig D., Henderson, Grant, Flannigan, Stuart, Oppo, Gian-Luca, Daley, Andrew J., Kuhr, Stefan, and Haller, Elmar

Subjects

Condensed Matter - Quantum Gases

Abstract

We experimentally study the excitation modes of bright matter-wave solitons in a quasi-one-dimensional geometry. The solitons are created by quenching the interactions of a Bose-Einstein condensate of cesium atoms from repulsive to attractive in combination with a rapid reduction of the longitudinal confinement. A deliberate mismatch of quench parameters allows for the excitation of breathing modes of the emerging soliton and for the determination of its breathing frequency as a function of atom number and confinement. In addition, we observe signatures of higher-order solitons and the splitting of the wave packet after the quench. Our experimental results are compared to analytical predictions and to numerical simulations of the one-dimensional Gross-Pitaevskii equation.

Published

2019

4. Collisionally Inhomogeneous Bose-Einstein Condensates with a Linear Interaction Gradient

Author

Di Carli, Andrea, primary, Henderson, Grant, additional, Flannigan, Stuart, additional, Colquhoun, Craig D., additional, Mitchell, Matthew, additional, Oppo, Gian-Luca, additional, Daley, Andrew J., additional, Kuhr, Stefan, additional, and Haller, Elmar, additional

Published

2020

5. Note : a simple laser shutter with protective shielding for beam powers up to 1 W

Author

Colquhoun, Craig D., Di Carli, Andrea, Kuhr, Stefan, and Haller, Elmar

Subjects

QC

Abstract

We present the design of an inexpensive and reliable mechanical laser shutter and its electronic driver. A camera diaphragm shutter unit with several sets of blades is utilized to provide fast blocking of laser light and protective shielding of the shutter mechanism up to a laser beam power of 1 W. The driver unit is based on an Arduino microcontroller with a motor-shield. Our objective was to strongly reduce construction effort and expenditure by limiting ourselves to a small number of modular parts, which are readily available. We measured opening and closing durations of less than 800 µs, and a timing jitter of less than 25 µs for the fastest set of blades. No degradation of the shutter performance was observed over 5·10^4 cycles.

Published

2018

6. Excitation Modes of Bright Matter-Wave Solitons

Author

Di Carli, Andrea, primary, Colquhoun, Craig D., additional, Henderson, Grant, additional, Flannigan, Stuart, additional, Oppo, Gian-Luca, additional, Daley, Andrew J., additional, Kuhr, Stefan, additional, and Haller, Elmar, additional

Published

2019

7. Syntheses, Hydrogen Bonding, and Metal Coordination Studies of New Ferrocene Peptide Conjugates

Author

Colquhoun, Craig D.

Subjects

Inorganic Chemistry, metal coordination, peptides, alanine, histidine, ferrocene conjugates, hydrogen bonding

Abstract

The main goal of the research was the synthesis of new ferrocene peptideconjugates, to study the role of hydrogen bonding interactions, and the coordinationproperties of these systems. Ferrocene peptide conjugates have been extensivelystudied as models of protein secondary structures. Of particular interest weredisubstituted ferrocene derivatives such as ferrocene dicarboxylic acid, which have beenshown to be important in the design of peptide mimics. The inter-ring spacing betweentwo cyclopentadienyl rings in ferrocene has shown to be appropriate for forminghydrogen bonds between conjugated peptide chains, which are attached to the twocyclopentadienyl rings. Inter-ring spacing has proven to be of great importance for theformation of stable hydrogen-bonded structures. Additionally, some of these ferrocenepeptide conjugates have the ability to coordinate metal ions. This is of interest becausethese systems have the potential to serve as active site mimics of metalloproteins. Thiswork focused on the synthesis, hydrogen bonding studies, and coordination propertiesof novel ferrocene peptide conjugates.

Published

2012

8. Note: A simple laser shutter with protective shielding for beam powers up to 1 W.

Author

Colquhoun CD, Di Carli A, Kuhr S, and Haller E

Abstract

We present the design of an inexpensive and reliable mechanical laser shutter and its electronic driver. A camera diaphragm shutter unit with several sets of blades is utilized to provide fast blocking of laser light and protective shielding of the shutter mechanism up to a laser beam power of 1 W. The driver unit is based on an Arduino microcontroller with a motor-shield. Our objective was to strongly reduce construction effort and expenditure by limiting ourselves to a small number of modular parts, which are readily available. We measured opening and closing durations of less than 800 μ s, and a timing jitter of less than 25 μ s for the fastest set of blades. No degradation of the shutter performance was observed over 5·10 4 cycles.

Published

2018