Prof Arzhang Ardavan

Magnetic field sensing beyond the standard quantum limit using 10-spin NOON states

(2008)

Authors:

Jonathan A Jones, Steven D Karlen, Joe Fitzsimons, Arzhang Ardavan, Simon C Benjamin, GAD Briggs, John JL Morton

Electronic transport characterization of Sc@ C82 single-wall carbon nanotube peapods

Journal of Applied Physics 104:8 (2008)

Authors:

AL Cantone, MR Buitelaar, CG Smith, D Anderson, GAC Jones, SJ Chorley, C Casiraghi, A Lombardo, AC Ferrari, H Shinohara, A Ardavan, J Warner, AAR Watt, K Porfyrakis, GAD Briggs

Abstract:

We present electrical transport and Raman measurements on individual single-wall carbon nanotubes filled with the paramagnetic metallofullerene Sc@ C82. We find nearly all devices to be metallic p -type conductors, which we tentatively attribute to bandstructure modification of the nanotubes by the encapsulated Sc@ C82 molecules. At low temperatures the peapod devices behave as quantum dots and transport is shown to be quantum coherent over distances of at least ∼100 nm. Kondo features are observed at the lowest measurement temperatures of 50 mK. Our results are of fundamental interest because of the long spin coherence times of the unpaired electrons on the Sc@ C82 molecules and the possibility this offers for studying one-dimensional spin chains in carbon nanotubes. © 2008 American Institute of Physics.

Solid-state quantum memory using the (31)P nuclear spin.

Nature 455:7216 (2008) 1085-1088

Authors:

JJ Morton, AM Tyryshkin, RM Brown, S Shankar, BW Lovett, A Ardavan, T Schenkel, EE Haller, JW Ager, SA Lyon

Abstract:

The transfer of information between different physical forms-for example processing entities and memory-is a central theme in communication and computation. This is crucial in quantum computation, where great effort must be taken to protect the integrity of a fragile quantum bit (qubit). However, transfer of quantum information is particularly challenging, as the process must remain coherent at all times to preserve the quantum nature of the information. Here we demonstrate the coherent transfer of a superposition state in an electron-spin 'processing' qubit to a nuclear-spin 'memory' qubit, using a combination of microwave and radio-frequency pulses applied to (31)P donors in an isotopically pure (28)Si crystal. The state is left in the nuclear spin on a timescale that is long compared with the electron decoherence time, and is then coherently transferred back to the electron spin, thus demonstrating the (31)P nuclear spin as a solid-state quantum memory. The overall store-readout fidelity is about 90 per cent, with the loss attributed to imperfect rotations, and can be improved through the use of composite pulses. The coherence lifetime of the quantum memory element at 5.5 K exceeds 1 s.

Solid-state quantum memory using the ³¹P nuclear spin

Nature 455:7216 (2008) 1085-1088

Authors:

JJL Morton, AM Tyryshkin, RM Brown, S Shankar, BW Lovett, A Ardavan, T Schenkel, EE Haller, JW Ager, SA Lyon

Abstract:

The transfer of information between different physical forms - for example processing entities and memory - is a central theme in communication and computation. This is crucial in quantum computation, where great effort must be taken to protect the integrity of a fragile quantum bit (qubit). However, transfer of quantum information is particularly challenging, as the process must remain coherent at all times to preserve the quantum nature of the information. Here we demonstrate the coherent transfer of a superposition state in an electron-spin 'processing' qubit to a nuclear-spin 'memory' qubit, using a combination of microwave and radio-frequency pulses applied to 31P donors in an isotopically pure 28Si crystal. The state is left in the nuclear spin on a timescale that is long compared with the electron decoherence time, and is then coherently transferred back to the electron spin, thus demonstrating the 31P nuclear spin as a solid-state quantum memory. The overall store-readout fidelity is about 90 per cent, with the loss attributed to imperfect rotations, and can be improved through the use of composite pulses. The coherence lifetime of the quantum memory element at 5.5 K exceeds 1 s. ©2008 Macmillan Publishers Limited. All rights reserved.

Temperature-dependent photoluminescence study of ErSc2N@C 80 and Er2ScN@C80 fullerenes

Physica Status Solidi (B) Basic Research 245:10 (2008) 1998-2001

Authors:

A Tiwari, G Dantelle, K Porfyrakis, A Ardavan, GAD Briggs

Abstract:

The photoluminescence study of the Er3+ ion in ErSc 2N@C80 and Er2ScN@C80 fullerenes in the temperature range of 5 K to 80 K is presented. New emission peaks are observed for both fullerenes above 20 K. These peaks arise from thermally populated crystal-field levels of the excited state. An anomalous behaviour of the PL peak area is observed with an increasing temperature which reveals an internal rearrangement of the cluster ErSc2N in ErSc 2N@C80. © 2008 Wiley-VCH Verlag GmbH & Co. KGaA.