The scope of this thesis is related to the electronic properties of quasi 1D systems probed by high field magnetotransport. Two different systems exhibiting quasi-1D confinement have been considered: carbon C60 peapods (C60@SWCNTs) and InAs semiconductor nanowires. The magnetotransport measurements on single nano-objets have been used to investigate the specific electronic structure of these 1D systems. In both cases, the high magnetic fields experiments have been supported by structural characterisation and conductance measurements at zero field.
The encapsulation of various molecules inside carbon nanotubes (CNTs), as for instance C60 fullerenes encapsulated in SWCNT, constitutes promising routes towards the tunability of the CNT conductance. Among the wide variety of filled CNTs, peapods represent a pioneer hybrid structure discovered in 1998. Since that time, their electronic structure has been subjected to intense and controversial theoretical studies together with a limited number of experimental realizations. In this thesis the electronic properties of individual fullerene peapods have been investigated by combining micro-Raman spectroscopy and magnetotransport measurements on the same devices. We bring evidence that the encapsulated C60 strongly modify the electronic band structure of semiconducting nanotubes in the vicinity of the charge neutrality point, including a rigid shift and a partial filling of the energy gap. In addition by playing with a selective UV excitation of the fullerene, we demonstrate that the electronic coupling between the C60 and the CNT is strongly modified by the partial coalescence of the C60 and their distribution inside the tube. The experimental results are supported by numerical simulations of the Density of States and the conductance of CNTs with coalesced fullerenes inside.
Semiconductor nanowires (sc-NWs) are being the subject of intense researches started a decade ago. They represent model systems for the exploration of the electronic properties inerrant to the quasi1-D confinement. Moreover they offer the possibility to play with band structure tailoring and carrier doping. In this direction III-V sc-NWs such as InAs NWs have played a particular role due to the smallest electron effective mass. We have studied the high magnetic field conductance of single nanowires. Prior to the high field measurements, the zero and low field investigations have demonstrated the weakly diffusive regime of the carrier transport in these wires. The high field investigations have revealed a drastic conductance drop above a critical field, which clearly rises with the Fermi energy. This effect is interpreted by the loss of conducting channels once all the magneto-electric subbands, shifted toward the high energy range by the magnetic field, have crossed the Fermi energy. Preliminary band structure calculations, taking into account the lateral and magnetic confinements, are in fairly good qualitative agreement with the observed result in the high field regime. This result is the first observation of band structure effects in magneto-transport experiments on sc-NWs.
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The scope of this thesis is related to the electronic properties of quasi 1D systems probed by high field magnetotransport. Two different systems exhibiting quasi-1D confinement have been considered: carbon C60 peapods (C60@SWCNTs) and InAs semiconductor nanowires. The magnetotransport measurements on single nano-objets have been used to investigate the specific electronic structure of these 1D systems. In both cases, the high magnetic fields experiments have been supported by structural characterisation and conductance measurements at zero field.
The encapsulation of various molecules inside carbon nanotubes (CNTs), as for instance C60 fullerenes encapsulated in SWCNT, constitutes promising routes towards the tunability of the CNT conductance. Among the wide variety of filled CNTs, peapods represent a pioneer hybrid structure discovered in 1998. Since that time, their electronic structure has been subjected to intense and controversial theoretical studies together with a limited number of experimental realizations. In this thesis the electronic properties of individual fullerene peapods have been investigated by combining micro-Raman spectroscopy and magnetotransport measurements on the same devices. We bring evidence that the encapsulated C60 strongly modify the electronic band structure of semiconducting nanotubes in the vicinity of the charge neutrality point, including a rigid shift and a partial filling of the energy gap. In addition by playing with a selective UV excitation of the fullerene, we demonstrate that the electronic coupling between the C60 and the CNT is strongly modified by the partial coalescence of the C60 and their distribution inside the tube. The experimental results are supported by numerical simulations of the Density of States and the conductance of CNTs with coalesced fullerenes inside.
Semiconductor nanowires (sc-NWs) are being the subject of intense researches started a decade ago. They represent model systems for the exploration of the electronic properties inerrant to the quasi1-D confinement. Moreover they offer the possibility to play with band structure tailoring and carrier doping. In this direction III-V sc-NWs such as InAs NWs have played a particular role due to the smallest electron effective mass. We have studied the high magnetic field conductance of single nanowires. Prior to the high field measurements, the zero and low field investigations have demonstrated the weakly diffusive regime of the carrier transport in these wires. The high field investigations have revealed a drastic conductance drop above a critical field, which clearly rises with the Fermi energy. This effect is interpreted by the loss of conducting channels once all the magneto-electric subbands, shifted toward the high energy range by the magnetic field, have crossed the Fermi energy. Preliminary band structure calculations, taking into account the lateral and magnetic confinements, are in fairly good qualitative agreement with the observed result in the high field regime. This result is the first observation of band structure effects in magneto-transport experiments on sc-NWs.
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