Professor Thorsten Hesjedal FInstP

Engineering of Bi2Se3 nanowires by laser cutting

The European Physical Journal Applied Physics EDP Sciences 66:1 (2014) 10401

Authors:

Piet Schönherr, Alexander A Baker, Patryk Kusch, Stephanie Reich, Thorsten Hesjedal

Vapour-liquid-solid growth of ternary Bi2Se2Te nanowires.

Nanoscale research letters 9:1 (2014) 127

Authors:

Piet Schönherr, Liam J Collins-McIntyre, Shilei Zhang, Patryk Kusch, Stephanie Reich, Terence Giles, Dominik Daisenberger, Dharmalingam Prabhakaran, Thorsten Hesjedal

Abstract:

: High-density growth of single-crystalline Bi2Se2Te nanowires was achieved via the vapour-liquid-solid process. The stoichiometry of samples grown at various substrate temperatures is precisely determined based on energy-dispersive X-ray spectroscopy, X-ray diffraction, and Raman spectroscopy on individual nanowires. We discuss the growth mechanism and present insights into the catalyst-precursor interaction.

Study of Gd-doped Bi2Te3 thin films: Molecular beam epitaxy growth and magnetic properties

Journal of Applied Physics 115 (2014) 2

Authors:

SE Harrison, LJ Collins-McIntyre, S Li, AA Baker, LR Shelford, Y Huo, A Pushp, SSP Parkin, JS Harris, E Arenholz, G van der Laan, T Hesjedal

Nonvolatile full adder based on a single multivalued Hall junction

SPIN World Scientific Publishing 3:2 (2013) 1350008

Authors:

SL Zhang, LJ Collins-McIntyre, JY Zhang, SG Wang, GH Yu, T Hesjedal

Abstract:

Multivalued logic devices are promising candidates for achieving high-density, low-power memory and logic functionalities. We present a ferromagnetic multilayer Hall junction device with four distinct resistance - and thus logic - states. The states can be encoded as a quaternary bit and decoded into two binary bits. We demonstrate a nonvolatile full adder that is based on a single Hall junction, the extraordinary Hall balance. The device can be easily integrated into complex logic circuits for logic-in-memory architectures.

Extraordinary hall balance

Scientific Reports 3 (2013)

Authors:

SL Zhang, Y Liu, LJ Collins-McIntyre, T Hesjedal, JY Zhang, SG Wang, GH Yu

Abstract:

Magnetoresistance (MR) effects are at the heart of modern information technology. However, future progress of giant and tunnelling MR based storage and logic devices is limited by the usable MR ratios of currently about 200% at room-temperature. Colossal MR structures, on the other hand, achieve their high MR ratios of up to 106% only at low temperatures and high magnetic fields. We introduce the extraordinary Hall balance (EHB) and demonstrate room-temperature MR ratios in excess of 31,000%. The new device concept exploits the extraordinary Hall effect in two separated ferromagnetic layers with perpendicular anisotropy in which the Hall voltages can be configured to be carefully balanced or tipped out of balance. Reprogrammable logic and memory is realised using a single EHB element. PACS numbers: 85.75.Nn,85.70.Kh,72.15.Gd,75.60.Ej.