This research focuses on the scale-up engineering of a silicon based quantum processor. This includes the fabrication of donor arrays by top-down and bottom-up techniques, interface electronics between several qubit implementations and the classical environment, and the development of application specific integrated circuits that are suitable for different qubit implementations. This research is a collaboration between seven Program Managers from The UNSW Sydney and the University of Melbourne.
Led by Professor Lloyd Hollenberg, Deputy Director of CQC²T, the Quantum Processor Development Program's objective is to develop comprehensive theoretical descriptions of quantum information processing and the development of related quantum technology applications. The program pays particular…
The Precision Qubit Processor Program led by Professor Michelle Y. Simmons has the ultimate goal of developing a scalable, phosphorus in silicon, quantum processor. Professor Simmons’s group leads the field internationally in making precision atomic…
Building a quantum computer is a major challenge in understanding the quantum effects that we want to put to practical use for computation. Along with that we have a big challenge in designing the control…
The Integrated Silicon Nano-Spintronics Program is led by Prof Andrew Dzurak. Based within the School of Electrical Engineering at UNSW Sydney, the Program provides the Centre with engineering design, modelling and nanofabrication of fully-configured silicon…
The Silicon Qubit Environment & Interface Program, led by Prof Sven Rogge at UNSW Sydney, aims to couple qubits in a robust manner from the atomic nano-meter length scale to macroscopic coupling via photons. On…
The Silicon Quantum Hardware Program is led by Professor Andrea Morello based at UNSW Sydney. The research focuses on experimental control, readout and coupling of single P-atom spin qubits in silicon, for the construction of…
The Directed Ion Implantation Program employs top-down deterministic methods for making devices by directing single ions to specific locations in silicon substrates that act as atomic qubits. Led by Professor David Jamieson, the research will…