Your search keyword '"Buehler, TM"' showing total 2 results

1. Progress in silicon-based quantum computing.

Author

Clark RG, Brenner R, Buehler TM, Chan V, Curson NJ, Dzurak AS, Gauja E, Goan HS, Greentree AD, Hallam T, Hamilton AR, Hollenberg LC, Jamieson DN, McCallum JC, Milburn GJ, O'Brien JL, Oberbeck L, Pakes CI, Prawer SD, Reilly DJ, Ruess FJ, Schofield SR, Simmons MY, Stanley FE, Starrett RP, Wellard C, and Yang C

Abstract

We review progress at the Australian Centre for Quantum Computer Technology towards the fabrication and demonstration of spin qubits and charge qubits based on phosphorus donor atoms embedded in intrinsic silicon. Fabrication is being pursued via two complementary pathways: a 'top-down' approach for near-term production of few-qubit demonstration devices and a 'bottom-up' approach for large-scale qubit arrays with sub-nanometre precision. The 'top-down' approach employs a low-energy (keV) ion beam to implant the phosphorus atoms. Single-atom control during implantation is achieved by monitoring on-chip detector electrodes, integrated within the device structure. In contrast, the 'bottom-up' approach uses scanning tunnelling microscope lithography and epitaxial silicon overgrowth to construct devices at an atomic scale. In both cases, surface electrodes control the qubit using voltage pulses, and dual single-electron transistors operating near the quantum limit provide fast read-out with spurious-signal rejection.

Published

2003

2. Density-dependent spin polarization in ultra-low-disorder quantum wires.

Author

Reilly DJ, Buehler TM, O'Brien JL, Hamilton AR, Dzurak AS, Clark RG, Kane BE, Pfeiffer LN, and West KW

Abstract

There is controversy as to whether a one-dimensional (1D) electron gas can spin polarize in the absence of a magnetic field. Together with a simple model, we present conductance measurements on ultra-low-disorder quantum wires supportive of a spin polarization at B=0. A spin energy gap is indicated by the presence of a feature in the range (0.5-0.7)x2e(2)/h in conductance data. Importantly, it appears that the spin gap is not constant but a function of the electron density. Data obtained using a bias spectroscopy technique are consistent with the spin gap widening further as the Fermi level is increased.

Published

2002