Universal conductance fluctuations and localization effects in InN nanowires connected in parallel

Abstract: The low-temperature quantum transport of InN nanowires grown by plasma-assisted molecular beam epitaxy is investigated. Two sets of nanowires with diameters of 100 and 45 nm originating from two different growth runs are studied. Magnetic-field-dependent as well as gate-dependent measurements of universal conductance fluctuations are performed to gain information on the phase-coherence in the electron transport. By analyzing the correlation field and the average fluctuation amplitude a phase-coherence length o… Show more

“…For Nyquist scattering τ ϕ is proportional to T −2/3 and therefore L ϕ is expected to be proportional to T −1/3 . [23][24][25] In our experiment the temperature dependence of L ϕ is about ∼T −0.3 at Kelvin temperatures and hence agrees with this model. But for milli-Kelvin temperature it gets weaker, suggesting a saturating behavior at a few hundred nanometers.…”

Phase coherent transport in graphene nanoribbons and graphene nanoribbon arrays

“…For Nyquist scattering τ ϕ is proportional to T −2/3 and therefore L ϕ is expected to be proportional to T −1/3 . [23][24][25] In our experiment the temperature dependence of L ϕ is about ∼T −0.3 at Kelvin temperatures and hence agrees with this model. But for milli-Kelvin temperature it gets weaker, suggesting a saturating behavior at a few hundred nanometers.…”

Phase coherent transport in graphene nanoribbons and graphene nanoribbon arrays

“…After analyzing experimental works on the study of phase-coherence length temperature dependence in structured materials [29,30,54,[56][57][58][59][60][61],…”

Weak localization and size effects in thin In 2 O 3 films prepared by autowave oxidation

“…The recent development in nanoscale material synthesis methods has made the fabrications of quasi-one-dimensional (Q1D) nanowires widely accessible. One of the experimental realizations of the marked quantum-interference effects is the observation of the universal conductance fluctuations (UCFs) [1-3] in Q1D metallic [4,5] and heavily doped semiconductor [6,7] nanowires. In sharp contrast to the classical thermal noise, the UCF magnitudes increase with reducing temperature T [8-11], owing to the inherent quantum nature of the electron waves traversing in a weakly random potential.…”

Time-dependent universal conductance fluctuations in IrO2 nanowires