Paul Stavrinou

Controlling radiative loss in quantum well solar cells

Journal of Physics D IOP Publishing 46:26 (2013) 264007

Authors:

NJ Ekins-Daukes, K-H Lee, L Hirst, A Chan, M F?hrer, J Adams, B Browne, KWJ Barnham, P Stavrinou, J Connolly, JS Roberts, B Stevens, R Airey, K Kennedy

Location, Location, Location ‐ Strategic Positioning of 2,1,3‐Benzothiadiazole Units within Trigonal Quaterfluorene‐Truxene Star‐Shaped Structures

Advanced Functional Materials Wiley 23:22 (2013) 2792-2804

Authors:

Colin R Belton, Alexander L Kanibolotsky, James Kirkpatrick, Clara Orofino, Saadeldin ET Elmasly, Paul N Stavrinou, Peter J Skabara, Donal DC Bradley

Drift-diffusion modeling of InP-based triple junction solar cells

Proceedings of SPIE--the International Society for Optical Engineering SPIE, the international society for optics and photonics 8620 (2013) 86201g-86201g-9

Authors:

MP Lumb, M González, CG Bailey, I Vurgaftman, JR Meyer, J Abell, M Yakes, R Hoheisel, JG Tischler, PN Stavrinou, M Fuhrer, NJ Ekins-Daukes, RJ Walters

Confined surface plasmon-polariton amplifiers.

Nano letters 13:3 (2013) 1323-1329

Authors:

Stéphane Kéna-Cohen, Paul N Stavrinou, Donal DC Bradley, Stefan A Maier

Abstract:

We demonstrate the realization of confined surface plasmon polariton amplifiers using a thin layer of the organic gain medium 4-dicyanomethylene-2-methyl-6-(p-dimethylaminostyryl)-4H-pyran dispersed in a tris(8-hydroxy-quinolinato)aluminum matrix. Complete loss compensation, which occurs at a pump fluence of approximately 200 μJ/cm(2), is directly observed in the time domain and studied for a range of waveguide lengths. The power dependence is also reported, and a significant net gain of 93 dB/mm is observed at the highest fluence.

On-demand patterning of nanostructured pentacene transistors by scanning thermal lithography.

Advanced materials (Deerfield Beach, Fla.) 25:4 (2013) 552-558

Authors:

Joseph E Shaw, Paul N Stavrinou, Thomas D Anthopoulos

Abstract:

Thermal scanning lithography is used to pattern semiconducting nanoribbon-like pentacene structures with ultrahigh spatial resolution onto arbitrary substrates in air. The method allows control of the pentacene crystal growth direction and domain-size distribution. By combining these quasi-one-dimensional nanoribbon-like structures with conductive electrodes and a suitable gate dielectric, functional p-channel transistors are demonstrated.