Dr Dharmalingam Prabhakaran

Andreev bound states in superconductor/ferromagnet point contact Andreev reflection spectra

Physical Review B American Physical Society 95:9 (2017) 094516

Authors:

KA Yates, LAB Olde Olthof, ME Vickers, Dharmalingam Prabhakaran, M Egilmez, JWA Robinson, LF Cohen

Abstract:

As charge carriers traverse a single superconductor ferromagnet interface, they experience an additional spin-dependent phase angle that results in spin mixing and the formation of a bound state called the Andreev bound state. Here we explore whether point contact Andreev reflection can be used to detect the Andreev bound state and, within the limits of our experiment, we extract the resulting spin mixing angle. By examining spectra taken from La1.15Sr1.85Mn2O7-Pb junctions, together with a compilation of literature data on highly spin polarized systems, we suggest that the existence of the Andreev bound state would resolve a number of long standing controversies in the literature of Andreev reflection, as well as defining a route to quantify the strength of spin mixing at superconductor-ferromagnet interfaces. Intriguingly, we find that for high transparency junctions, the spin mixing angle appears to take a relatively narrow range of values across all the samples studied. The ferromagnets we have cho sen to study share a common property in terms of their spin arrangement, and our observations may point to the importance of this property in determining the spin mixing angle under these circumstances.

Magnetic excitations of the charge stripe electrons below half doping in La2-xSrxNiO4 (x = 0.45, 0.4)

Physical Review B American Physical Society 95:6 (2017) 064403

Authors:

PG Freeman, K Hradil, RA Mole, P Cermak, Dharmalingam Prabhakaran

Abstract:

The low energy magnetic excitation spectrum of charge stripe ordered La2-xSrxNiO4, x=0.4 and x=0.45 samples, were studied by neutron scattering. Two excitation modes are observed in both materials, one from the ordered magnetic moments, and a second mode consistent with pseudo-one-dimensional antiferromagnetic excitations of the charge stripe electrons (q-1D). The dispersion of the q-1D excitation follows the same relation as in x=1/3 composition, with even spectral weight in the two counterpropagating branches of the x=0.4 sample, however in the x=0.45 sample only one dispersion branch has any measurable spectral weight. The evolution of the q-1D excitations on doping to the checkerboard charge ordered phase is discussed.

Effect of doping and defects in pyrochlore compounds

ACTA CRYSTALLOGRAPHICA A-FOUNDATION AND ADVANCES 73 (2017) C1020-C1020

Authors:

Dharmalingam Prabhakaran, Sichen Wang, Richard Brearton, Andrew Boothroyd

Layer-by-layer epitaxial thin films of the pyrochlore Tb2Ti2O7.

Nanotechnology Institute of Physics 28:5 (2016) 055708

Authors:

L Bovo, CM Rouleau, Dharmalingam Prabhakaran, ST Bramwell

Abstract:

Layer-by-layer epitaxial growth of the pyrochlore magnet Tb2Ti2O7 on the isostructural substrate Y2Ti2O7 results in high-quality single crystal films of up to 60 nm thickness. Substrate-induced strain is shown to act as a strong and controlled perturbation to the exotic magnetism of Tb2Ti2O7, opening up the general prospect of strain-engineering the diverse magnetic and electrical properties of pyrochlore oxides.

Hall effect in charged conducting ferroelectric domain walls.

Nature communications 7 (2016) 13764

Authors:

MP Campbell, JPV McConville, RGP McQuaid, D Prabhakaran, A Kumar, JM Gregg

Abstract:

Enhanced conductivity at specific domain walls in ferroelectrics is now an established phenomenon. Surprisingly, however, little is known about the most fundamental aspects of conduction. Carrier types, densities and mobilities have not been determined and transport mechanisms are still a matter of guesswork. Here we demonstrate that intermittent-contact atomic force microscopy (AFM) can detect the Hall effect in conducting domain walls. Studying YbMnO₃ single crystals, we have confirmed that p-type conduction occurs in tail-to-tail charged domain walls. By calibration of the AFM signal, an upper estimate of ∼1 × 10¹⁶ cm^-3 is calculated for the mobile carrier density in the wall, around four orders of magnitude below that required for complete screening of the polar discontinuity. A carrier mobility of∼50 cm²V^-1s^-1 is calculated, about an order of magnitude below equivalent carrier mobilities in p-type silicon, but sufficiently high to preclude carrier-lattice coupling associated with small polarons.