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dc.contributor.authorSonne, Gustav
dc.date.accessioned2011-03-25T09:16:14Z
dc.date.available2011-03-25T09:16:14Z
dc.date.issued2011-03-25
dc.identifier.isbn978-91-628-8244-0
dc.identifier.urihttp://hdl.handle.net/2077/24289
dc.description.abstractOver the last two decades nanotechnology has been a very active field of scientific research, both from fundamental perspectives as well as for applications in technology and consumer goods. In this thesis, theoretical work on quantum mechanical effects on charge transport in nanoelectromechanical systems is presented. In particular, the effects of electron-vibron interactions in suspended nanowire structures are analysed and discussed. The thesis is structured around the appended scientific publications by the author. Also included is an introductory section where the underlying theory and motivation is presented. This introduction forms the basis on which the subsequent material and appended papers is based. The work presented in the appended papers considers systems comprising suspended oscillating nanowires, primarily in the form of carbon nanotubes. Central to these studies is the interaction between the charge transport and the mechanical motion of the nanowires. For the systems analysed in this thesis, these interactions are mediated through transverse magnetic fields, the effect of which is studied in various system setups. In particular, three topics of mesoscopic phenomena are presented; i) a temperature-independent current deficit due to interference effects between different electronic tunnelling paths over the nanowire-junction, ii) pumping of the mechanical vibrations in a low transparency superconducting junction, and iii) cooling of the mechanical vibrations in both current- and voltage-biased superconducting junctions. The outcome of the presented work is a number of interesting physical predictions for the electromechanics of suspended nanowires. These results are shown to be experimentally observable in systems with high mechanical resonance frequencies and if sufficiently strong electromechanical coupling can be achieved. Once these conditions are fulfilled, the predicted results are of interest both from a fundamental perspective in that they probe the underlying quantum nature of the systems, but also for sensing applications where quantum limited resolution could be experimentally achievable.sv
dc.language.isoengsv
dc.relation.haspartI. Sonne, G. (2009). Temperature-independent current deficit due to induced quantum nanowire vibrations. New Journal of Physics, 11, 073037.::doi::10.1088/1367-2630/11/7/073037sv
dc.relation.haspartII. Sonne, G., Shekhter, R. I., Gorelik, L. Y., Kulinich, S. I., & Jonson, M. (2008). Superconducting pumping of nanomechanical vibrations. Physical Review B, 78, 144501.::doi::10.1103/PhysRevB.78.144501sv
dc.relation.haspartIII. Sonne, G., Pena-Aza, M. E., Gorelik, L. Y., Shekhter, R. I., & Jonson, M. (2010). Cooling of a Suspended Nanowire by an ac Josephson Current Flow. Physical Review Letters, 104, 226802.::doi::10.1103/PhysRevLett.104.226802sv
dc.relation.haspartIV. Sonne, G., & Gorelik, L. Y. (2011). Ground-state cooling of a suspended nanowire through inelastic macroscopic quantum tunneling in a current-biased Josephson junction. Unpublished manuscript.sv
dc.subjectNanoelectromechanical systemssv
dc.subjectGround-state coolingsv
dc.subjectSuperconducting weak linkssv
dc.subjectCarbon nanotubessv
dc.subjectNon-linear resonancesv
dc.titleMesoscopic phenomena in the electromechanics of suspended nanowiressv
dc.typeText
dc.type.svepDoctoral thesiseng
dc.gup.mailgustav.sonne@physics.gu.sesv
dc.type.degreeDoctor of Philosophysv
dc.gup.originGöteborgs universitet. Naturvetenskapliga fakultetensv
dc.gup.departmentDepartment of Physics ; Institutionen för fysiksv
dc.gup.defenceplaceFredagen den 15 april 2011, kl. 10.00, Kollektorn, Institutionen för mikroteknologi och nanovetenskap (Chalmers), Kemivägen 9sv
dc.gup.defencedate2011-04-15
dc.gup.dissdb-fakultetMNF


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