Professor Thorsten Hesjedal FInstP

Three dimensional magnetic abacus memory

Scientific Reports Nature Publishing Group 4:1 (2014) 6109

Authors:

Shilei Zhang, JingYan Zhang, Alexander Baker, ShouGuo Wang, GuangHua Yu, Thorsten Hesjedal

Abstract:

Stacking nonvolatile memory cells into a three-dimensional matrix represents a powerful solution for the future of magnetic memory. However, it is technologically challenging to access the data in the storage medium if large numbers of bits are stacked on top of each other. Here we introduce a new type of multilevel, nonvolatile magnetic memory concept, the magnetic abacus. Instead of storing information in individual magnetic layers, thereby having to read out each magnetic layer separately, the magnetic abacus adopts a new encoding scheme. It is inspired by the idea of second quantisation, dealing with the memory state of the entire stack simultaneously. Direct read operations are implemented by measuring the artificially engineered ‘quantised’ Hall voltage, each representing a count of the spin-up and spin-down layers in the stack. This new memory system further allows for both flexible scaling of the system and fast communication among cells. The magnetic abacus provides a promising approach for future nonvolatile 3D magnetic random access memory.

Comparison of Au and TiO2 based catalysts for the synthesis of chalcogenide nanowires

Applied Physics Letters AIP Publishing 104:25 (2014) 253103

Authors:

P Schönherr, D Prabhakaran, W Jones, N Dimitratos, M Bowker, T Hesjedal

Modelling ferromagnetic resonance in magnetic multilayers: Exchange coupling and demagnetisation-driven effects

Journal of Applied Physics AIP Publishing 115:17 (2014) 17d140

Authors:

AA Baker, CS Davies, AI Figueroa, LR Shelford, G van der Laan, T Hesjedal

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.