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Prof. Dr. Stephan Roche

Profil

Derzeitige StellungProfessor W-3 und Äquivalente
FachgebietTheoretische Physik der Kondensierten Materie,Halbleiterphysik
KeywordsGraphene, device simulation, topological insulators, quantum spin transport, carbon nanotubes
Auszeichnungen

2009: Friedrich Wilhelm Bessel Research Award

Aktuelle Kontaktadresse

LandSpanien
OrtBellaterra
Universität/InstitutionConsejo Superior de Investigaciones Cientificas (CSIC)
Institut/AbteilungCatalan Institute of Nanoscience and Nanotechnology (ICN2)

Gastgeber*innen während der Förderung

Prof. Dr. Gianaurelio CunibertiInstitut für Werkstoffwissenschaft, Technische Universität Dresden, Dresden
Prof. Dr. Bernd BüchnerInstitut für Festkörperforschung, Leibniz-Institut für Festkörper- und Werkstoffforschung Dresden (IFW) e.V., Dresden
Prof. Dr. Gotthard SeifertProfessur für Physikalische Chemie / Elektrochemie, Technische Universität Dresden, Dresden
Beginn der ersten Förderung01.04.2009

Programm(e)

2008Friedrich Wilhelm Bessel-Forschungspreis-Programm

Projektbeschreibung der*des Nominierenden

Dr. Roche is an outstanding scientist in the field of Theoretical Nanosciences with a broad experience in studying quantum transport and computational modeling of low dimensional systems and complex materials. He combines a broad variety of theoretical tools. His research activities have yielded cutting-edge achievements in the fields of carbon nanotubes, DNA, 2D graphene, and semiconducting nanowires. During his stay in Dresden, Dr. Roche will - among other topics - concentrate on investigating magnetotransport and quantum Hall effects in low dimensional 2D graphene, and charge transport in DNA.

Publikationen (Auswahl)

2011W. Li, H. Sevincli, S. Roche, G. Cuniberti: Efficient linear scaling method for computing the thermal conductivity of disordered materials . In: Physical Review B (Viewpoint) , 2011, 155416
2011E. Erdogan, I. Popov, C. G. Rocha, G. Cuniberti, S. Roche, G. Seifert: Engineering carbon chains from mechanically stretched graphene-based materials . In: Physical Review B- Rapid Communication, 2011, 041401
2011Mark H. Rümmeli, Claudia G. Rocha, Frank Ortmann, Imad Ibrahim, Haldun Sevincli, Felix Börrnert, Jens Kunstmann, Alicja Bachmatiuk, Markus Pötschke, Masashi Shiraishi, M. Meyyappan, Bernd Büchner, Stephan Roche and Gianaurelio Cuniberti : Graphene: Piecing it Together . In: Advanced Materials, 2011, 4471-4490
2011C. G. Rocha, M. H. Rümmeli, I. Ibrahim, H. Sevincli, F. Börrnert, J. Kunstmann, A. Bachmatiuk, M. Pötschke, W. Li, S. A. M. Makharza, S. Roche, B. Büchner, and G. Cuniberti : Graphene: Synthesis and Applications . Taylor and Francis Books-CRC Press, 2011
2011T. Kawai, M. Poetschke, Y. Miyamoto, C. G. Rocha, S. Roche, and G. Cuniberti: Mechanically-induced transport switching effect in graphene-based nanojunctions. In: Physical Review B (rapid Communication), 2011, 241405-1-241405-4
2010W. Li, H. Sevincli, G. Cuniberti, S. Roche: Phonon transport in large scale carbon-based disordered materials: Implementation of an efficient order-N and real-space Kubo methodology . In: Physical Review B (Rapid Comm.) , 2010, 041410
2010M. Pötschke, C. G. Rocha, L. E. F. Foa Torres, S. Roche, and G. Cuniberti: Modeling graphene-based nanoelectromechanical devices . In: Physical Review B , 2010, 193404
2009Stephan Roche Alejandro Lopez Bezanilla Francois Triozon: Chemical Functionalization Effects on Armchair Graphene Nanoribbon Transport. In: Nano Letters, 2009, 2537-2541
2009Stephan Roche Blanca Biel Francois Triozon Xavier Blase: Chemically Induced Mobility Gaps in Graphene Nanoribbons: A Route for Upscaling Device Performances. In: Nano Letters, 2009, 2725-2729
2009Stephan Roche Alessandro Cresti: Edge Disorder dependent Transport Length Scales in Graphene Nanoribbons: From Klein Defects to the Superlattice limit.. In: Physical Review B , 2009, 23304-23308
2009S. Lakshmi, S. Roche, and G. Cuniberti: Spin valve effect in zigzag graphene nanoribbons by defect engineering . In: Physical Review B , 2009, 193404