Magnetotransport measurements in low-dimensional Ga←0←.←4←7In←0←.←5←3As/Al←0←.←4←8In←0←.←5←2As devices

Leonard, Thomas Philip

January 1991

No description available.

530.41

Semiconductors; Electronic transport

Electronic transport in III-V semiconductors and semiconductor devices

Newson, D. J.

January 1986

No description available.

530.41

Electronic transport in metals

The electronic transport properties of amorphous metals : Measurement and numerical calculations

Hickey, B. J.

January 1987

No description available.

530.41

Electronic transport in metals

Relaxation Time Approximations in PAOFLOW 2.0

Jayaraj, Anooja

05 1900

Electronic transport properties have been used to classify and characterize materials and describe their functionality. Recent surge in computational power has enabled computational modelling and accelerated theoretical studies to complement and accelerate experimental discovery of novel materials. This work looks at methods for theoretical calculations of electronic transport properties and addresses the limitations of a common approximation in the calculation of these properties, namely, the constant relaxation time approximation (CRTA). This work takes a look at the limitations of this approximation and introduces energy and temperature dependent relaxation times. This study is carried out on models and real systems and compared with experiments.

Thermoelectrics

Electronic transport

Scattering time

Synthesis and characterization of nano-crystalline diamond films

Chimowa, George

13 September 2011

MSc, Faculty of Science, University of the Witswatersrand, 2011 / The objective of this project is to understand the details of the electronic transport in low dimensional carbon structures at low temperatures as well as high magnetic fields. The emphasis is on the quasi-2 dimensional thin grain boundary regions of nanodiamond films and one dimensional carbon nanotubes. As such nitrogen “doped” and undoped nanodiamond films were synthesized by the hot filament chemical vapor deposition method (HFCVD). The films were micro-structurally and electrically characterized using several techniques such as Raman spectroscopy, scanning electron microscopy, transmission electron microscopy, atomic force microscopy and magnetoresistance (MR) measurements. The electronic transport properties were compared to the films deposited by microwave plasma enhanced chemical vapour deposition (MWCVD). The conductivity revealed a typical semiconducting and semi-metallic behavior for the HFCVD films depending on the nitrogen percentage in the chamber. The dephasing time of the electronic wave function was found to be weakly temperature dependant i.e. τ T-p with p < 1, a behavior reported in artificial superlattices. These results show potential application of these materials in novel nano-electronic devices. Previously the transport mechanism in nanodiamond films has been attributed to hopping conduction in the grain boundaries which is predominately disordered sp2 phases. Our studies on nanodiamond films have however shown different mechanisms in these films. We observed very little contribution from hopping and pronounced weak localization contributions in nanodiamond films. We thus establish the significance of tunneling transport in nanodiamond films. We also studied the electronic transport in films of metal filled multiwalled carbon nanotubes which show significant contribution from the hopping mechanism and a negative magnetoresistance at low fields that crosses over into positive MR at high magnetic fields.

nanodiamond films

tunneling transport

magnetoresistance

electronic transport

Gated Hall and field-effect transport characterization of e-mode ZnO TFTs

Anders, Jason C.

20 August 2021

No description available.

Electrical Engineering

gated Hall

electronic transport

mobility

Electronic transport properties of carbon nanotubes: the impact of atomic charged impurities

Tsuchikawa, Ryuichi

01 January 2015

Even changing one atom in nanoscale materials is expected to alter their properties due to their small physical sizes. Such sensitivity can be utilized to modify materials' properties from bottom up and is essential for the utility of nanoscale materials. As such, the impact of extrinsic atomic adsorbates was measured on pristine graphene and a network of carbon nanotubes using atomic hydrogen, cesium atoms, and dye molecules. In order to further quantify such an atomic influence, the resistance induced by a single potassium atom on metallic and semiconducting carbon nanotubes was measured for the first time. Carbon nanotubes are sensitive to adsorbates due to their high surface-to-volume ratio. The resistance arising from the presence of extrinsic impurity atoms depends on the types of nanotubes. Metallic carbon nanotubes are resilient to a long-ranged, Coulomb-like potential, whereas semiconducting carbon nanotubes are susceptible to these impurities. The difference in the scattering strength originates from the chirality of carbon nanotubes, which defines their unique electronic properties. This difference had not directly measured experimentally because of the issue of contact resistance, the difficulty of chirality identification, and the uncertainty in the number of impurity atoms introduced on carbon nanotubes. We synthesized atomically clean, long ( > 100 ?m) carbon nanotubes, and their chirality was identified by Rayleigh scattering spectroscopy. We introduced potassium atoms on the nanotubes to impose a long-range, Coulomb potential and measured the change in resistivity, excluding the contact resistance, by plotting the resistance as a function of the carbon nanotube length. The flux of potassium atoms coming onto the nanotubes was monitored by quartz crystal microbalance, and the scattering strength of a single potassium atom was deduced from the change in resistivity and the density of potassium atoms on the nanotubes. We found that the scattering strength of potassium atoms on semiconducting nanotubes depends on the charge carrier type (holes or electrons). Metallic nanotubes were found to be less affected by the presence of potassium atoms than semiconducting nanotubes, but the scattering strength showed a large dependence on Fermi energy. These experimental results were compared to theoretical simulations, and we found a good agreement with the experiments. Our findings provide crucial information for the application of carbon nanotubes for electronic devices, such as transistors and sensors.

Carbon nanotubes

graphene

electronic transport

Physics

Transport Theory in Metals

White, Brian

04 1900

<p> The theoretical formulation of the electronic transport properties (in the absence of a magnetic field) of pure single crystals of simple metals is extended to incorporate the effect of a non~spherical Fermi surface, using a multiple orthogonalized plane wave description of the conduction electrons. Two approaches are considered, one using a variational principle, and the other employing a scattering time approximation. </p> <p> Formal results for the electrical resistivity and the electronic contribution to the thermal resistivity are expressed in terms of effective phonon frequency distributions. These distributions are particularly convenient for numerical computations and are generalization: of those previously used for the case of a spherical Fermi surface. </p> <p> The generalization of the scattering time method to dilute nonmagnetic substitutional alloys is applied to hexagonal close~packed metalsc It is shown that the addition of small amounts of impurities to pure Zn leads to measurable changes in the temperature dependence of the electrical resistivity ratio (see text for ratio with symbols). The corresponding deviations front Matthiessen's rule for polycrystalline samples are also calculated. </p> / Thesis / Master of Science (MSc)

transport theory

metal

electronic transport

single crystals

Transport Theory for Metals with Excitonic Instabilities

Breitkreiz, Maxim

14 December 2015

Metals with excitonic instabilities are multiband systems with significant electron-electron interaction. The electronic transport in such systems is affected by collective fluctuations of the electrons, leading to anomalous features in the measured transport coefficients. Many of these anomalies have not been well understood because the transport mechanisms in these systems tend to be rather complex. The complexity arises, on the one hand, from the multiband nature and, on the other, from the anisotropic scattering of electrons accompanied by emitting or absorbing collective fluctuations. Previous works considering scattering due to collective fluctuations have mainly focused on single-band systems, for example in the context of the normal-state transport in cuprates. The recent discovery of high-temperature superconductivity in iron pnictides has renewed the interest in multiband systems. Exploring the transport mechanisms in multiband systems, I find some interesting new aspects, which do not occur in single-band systems. In particular, anisotropic scattering in a model with electronlike and holelike Fermi surfaces can lead to a negative conductivity contribution of the minority carriers, i.e., in an electric field, the minority carriers drift in the direction opposite of what one would expect based on their charge. I show that this effect can explain a reduced magnetoresistance in connection with an enhanced Hall coefficient, which has been measured in pnictides. Of particular interest are multiband models with hot spots on the Fermi surface, in part because of their relevance for the iron pnictides. Hot spots are states with enhanced scattering and therefore reduced excitation lifetimes. In single-band systems, the hot spots are found to have a much lower contribution to the total conductivity than other parts of the Fermi surface, which leads to the so-called hot-spot structure. I show that in the multiband case, the conductivity contributions are much more isotropic around the Fermi surface so that hot spots contribute to transport with a similar strength as other parts of the Fermi surface. I discuss this effect on the basis of an approximate analytical solution of the transport problem and numerically calculate the temperature dependence of several transport coefficients. It turns out that in the nematic phase of iron pnictides, the unexpectedly strong conductivity contribution of hot spots can explain the puzzling behavior of the resistive anisotropy. I show that the experimental observations can be explained within a scenario in which the anisotropy is mainly due to the broken symmetry of the spin-fluctuation spectrum in the nematic phase. In the spin-density-wave state, strongly anisotropic scattering can arise due to the propagating magnons. Using a two-band model relevant for iron pnictides, I find that this scattering can lead to an unusual interruption of the orbital motion of electrons in the magnetic field. As a consequence, the low-field magnetoresistance is linear with an alternating sign of the slope as a function of the direction of the current. In strong magnetic fields, the interrupted orbital motion makes the system unstable, which is characterized by a drop of the resistivity to zero.

Semiklassik

Elektronischer Transport

semiclassic

electronic transport

ddc:530

rvk:UO 4080

Transporte Eletrônico em Phased Arrays de Nanofitas de Grafeno

Araújo, Francisco Ronan

January 2017

ARAÚJO, F. R. V. Transporte Eletrônico em Phased Arrays de Nanofitas de Grafeno. 2017. 70 f. Dissertação (Mestrado em Física) – Centro de Ciências, Universidade Federal do Ceará, Fortaleza, 2017. / Submitted by Pós-Graduação em Física (posgrad@fisica.ufc.br) on 2017-08-23T17:06:25Z No. of bitstreams: 1 2017_dis_frvaraujo.pdf: 3006955 bytes, checksum: 96cafe22b25ecd5c8d4c555c7a4a5c83 (MD5) / Approved for entry into archive by Giordana Silva (giordana.nascimento@gmail.com) on 2017-08-23T17:44:16Z (GMT) No. of bitstreams: 1 2017_dis_frvaraujo.pdf: 3006955 bytes, checksum: 96cafe22b25ecd5c8d4c555c7a4a5c83 (MD5) / Made available in DSpace on 2017-08-23T17:44:16Z (GMT). No. of bitstreams: 1 2017_dis_frvaraujo.pdf: 3006955 bytes, checksum: 96cafe22b25ecd5c8d4c555c7a4a5c83 (MD5) Previous issue date: 2017 / Graphene, a layer of carbon atoms arranged in a honeycomb crystal lattice, has remarkable physical properties. After its experimental obtaining in 2004 by A. K. Geim and K. S. Novoselov, several researches were carried out aiming to understand such physical properties and several possibilities of applications were proposed. At the low energy limit, there is a linearity relationship between energy and momentum for the electric charge carriers in this material and, therefore, they behave as relativistic particles of zero mass, described by the Dirac equation. One of the implications is that the electron-associated eigenfunctions that cross a potential barrier may not undergo damping under certain circumstances, a phenomenon known as Klein's paradox. Even without damping, these eigenfunctions acquire a phase factors that may depend only on the height and width values of the potential barrier. In this study, we investigate the properties transport in two electronic devices that use this phenomenon and that may be associated to phased arrays (electronic systems that have several emitters of waves, mechanically or electromagnetic, properly organized). We studied the electronic transport mechanisms in these physical systems and performed numerical simulations of electrical conductance as a function of energy and electrical conductance as a function of the electric potential and it was observed that the direction of propagation of the electrons can be controlled by varying the values of height and width of potential barriers. / O grafeno, uma camada de átomos de carbono arranjados em uma rede cristalina honeycomb (favo de mel), possui propriedades físicas notáveis. Após sua obtenção experimental em 2004 por A. K. Geim e K. S. Novoselov, várias pesquisas foram realizadas objetivando compreender tais propriedades físicas e diversas possibilidades de aplicações foram propostas. No limite de baixas energias, existe uma relação de linearidade entre a energia e o momento para os portadores de carga elétrica nesse material e, com isso, os mesmos comportam-se como partículas relativísticas de massa nula, descritas pela equação de Dirac. Uma das implicações disso é que as autofunções associadas aos elétrons que atravessam uma barreira de potencial podem não sofrer amortecimento em dadas circunstâncias, fenômeno esse conhecido como paradoxo de Klein. Mesmo sem sofrer amortecimento, essas autofunções adquirem fatores de fase que podem depender apenas dos valores de altura e largura da barreira de potencial. Nesse trabalho investigamos as propriedades de transporte em dois dispositivos eletrônicos que utilizam-se desse fenômeno e que podem ser associados a phased arrays (sistemas eletrônicos que possuem vários emissores de ondas, mecânicas ou eletromagnéticas, devidamente organizados). Estudamos os mecanismos de transporte eletrônico nesses sistemas físicos e realizamos simulações numéricas da condutância elétrica em função da energia e da condutância elétrica em função do potencial elétrico e observamos que a direção de propagação dos elétrons pode ser controlada através da variação dos valores de altura e largura das barreiras de potencial.

Nanofitas de grafeno

Transporte eletrônico

Graphene nanoribbons

Electronic transport