The group have been awarded an InnovateUK grant as part of the ISCF “Commercialising Quantum Technologies” call. This 18month project led by Nanoco Technologies (Widnes) and David Binks (Manchester) will explore singly-doped quantum dots as a platform for quantum technologies. The project runs from August 2022 to January 2024.
This project will recruit one postdoctoral researcher to work on high-throughput single-dot spectroscopy, to be advertised soon.
The group has secured funding for a 3-year license of NextNano for quantum device simulation. This is part of the University of Manchester’s COVID research-recovery fund, and will be led by group member Nikesh.
Patrick and colleague Jessica Boland have received short-term pump-prime funding to combine single-photon spectroscopy with scattering-type near-field microscopy. The project, running from February to June will employ one postdoc for a proof-of-principle system.
The group has been awarded funds to purchase a new ultrafast laser facility for the Photon Science Institute through an EPSRC Core Equipment Award (EP/V036343/1). This grant will be used to replace the aging Coherent RegA system with a turn-key highly tunable ultrafast laser system with optical parametric amplifier – details to follow!
Patrick has been awarded a 4-year research fellowship from UKRI for a project on “big-data for nano-electronics”. This Future Leaders Fellowship will enable Patrick to focus on building a research group to develop a new methodology for accelerating the study of functional nanotechnology.
The modern world runs on nanotechnology; we are connected by a fibre-network using nanostructured lasers, and use computers and phones made of nanometre scale transistors. The next generation of nanotechnology promises to incorporate multiple functionalities into single nanomaterial elements; this is “functional nanotechnology”. Here, the size of the material itself provides functionality – for instance for sensing, computing, or interacting with light. The most powerful and scalable approaches to making these structures use bottom-up or “self-assembled” methods; however, as this production technique emerges from the laboratory and into industry, issues such as yield, heterogeneity, and functional parameter spread have arisen.
Functional performance in these nanomaterials is determined by geometry. As such, variations in size or composition affect performance in complex ways. In this project, I will combine high-speed and high-throughput techniques to measure the shape, composition and performance of hundreds of thousands of functional nanoparticles from each production run. By combining this big data with statistical analytics, I will create a new methodology to understand and then optimize cutting-edge functional nanomaterials, working with academic partners in Cambridge, University College London, Strathclyde, Lund (Sweden) and the Australian National University, and industrial partners including AIXTRON and Nanoco.
The ultimate goal of this project is to enable demonstration and scale-up of transformative devices based on novel nanotechnology, for sensing, computing, telecommunication and quantum technology.
Patrick Parkinson (Manchester) and Ken Crozier (Melbourne) have been awarded linkage scheme funding to establish a collaboration.
This funding, established by the two universities, will allow bilateral exchanges to exploit areas of expertise at the two institutions. This project will explore nanostructured silicon materials developed by the Crozier group using ultrafast spectroscopic techniques in the Parkinson group.
The first exchange will see Patrick visit Melbourne in February 2018.
The group has been awarded a grant by the Royal Society to develop a new optical instrument known as the i-TCSPC. The Paul Instrument Fund, established by the late RW Paul, is intended to help the design and construction of a new piece of apparatus.
The new apparatus will leverage single-photon interference to increase the throughput and speed of spectral acquisition for extremely-low intensity and rapidly varying signals, with potential application in nanotechnology, metrology, and life sciences.
Work on the £52k project will begin in October 2016, and run for two years.