Potential summer scholars research projects

The Research School of Physics & Engineering performs research at the cutting edge of a wide range of disciplines.

By undertaking your own research project at RSPE you could open up an exciting career in science.

Search

Filter projects

Quantum Devices and Technology

Diamond quantum computing and communications

This project aims to engineer diamond quantum computers and communication networks.

Dr Marcus Doherty

Discovering quantum defects in diamond and related materials

This project aims to discover and study defects in diamond and related materials that are suitable for quantum technology.

Dr Marcus Doherty, Professor Neil Manson

Developing a planar waveguide photonic quantum processor

This project aims to develop a photonic quantum processor based on a planar waveguide architecture incorporating rare-earth doped crystals.

Associate Professor Matthew Sellars, Associate Professor Stephen Madden

Storing quantum entangled states of light

In this project you will demonstrate the storage of quantum entangled states of light using quantum memories based on rare-earth doped crystals.

Associate Professor Matthew Sellars, Dr Rose Ahlefeldt, Dr Kate Ferguson

Developing a quantum memory for the 1550 nm optical communication band

In this project you will develop a quantum memory for storing light at 1550 nm using erbium doped crystals.

Associate Professor Matthew Sellars, Dr Kate Ferguson

High storage capacity quantum memories

This project aims to develop high capacity quantum memories for light by using novel rare earth crystals.

Dr Rose Ahlefeldt, Associate Professor Matthew Sellars

Quantum microscopes for revolutionary interdisciplinary science

This project aims to invent and apply quantum microscopes to solve major problems across science.

Dr Marcus Doherty

Second Harmonic Generation for Quantum Optics Applications

Student will develop a source of laser light at 775nm that will be utilised for pumping of squeezing cavities  

Professor Ping Koy Lam, Dr Ben Buchler

Development of Squeezed Laser Sources for Quantum Communication

Student will build and characterise a new source of quantum squeezed light genearted from an optical parametric oscillator

Professor Ping Koy Lam, Dr Ben Buchler

Source-independent quantum random number generator

We aim to generate random numbers by performing orthogonal quadrature homodyne measurements without actually knowing or trusting the quantum state that we are measuring.

Dr Syed Assad, Professor Ping Koy Lam, Mr Jing-Yan Haw

Beam matching using machine learning

This project aims to use a machine learning algorithm to perform beam alignment in an optics experiment. It would involve mode-matching two optical beams using motorised mirror mounts. Additional degrees of freedom like lens positions and beam polarisation can be added later.

Dr Syed Assad, Mr Aaron Tranter, Mr Harry Slatyer

Optical quantum memory

An optical quantum memory will capture a pulse of light, store it and then controllably release it. This has to be done without ever knowing what you have stored, because a measurement will collapse the quantum state. We are exploring a "photon echo" process to achieve this goal.

Dr Ben Buchler

Updated:  17 August 2017/ Responsible Officer:  Director, RSPE/ Page Contact:  Physics Webmaster