Global ETD Search

11	Impact of Disorder on Spin Dependent Transport Phenomena Saidaoui, Hamed Ben Mohamed 03 July 2016 (has links) The impact of the spin degree of freedom on the transport properties of electrons traveling through magnetic materials has been known since the pioneer work of Mott [1]. Since then it has been demonstrated that the spin angular momentum plays a key role in the scattering process of electrons in magnetic multilayers. This role has been emphasized by the discovery of the Giant Magnetoresistance in 1988 by Fert and Grunberg [2, 3]. Among the numerous applications and effects that emerged in mesoscopic devices two mechanisms have attracted our attention during the course of this thesis: the spin transfer torque and the spin Hall effects. The former consists in the transfer of the spin angular momentum from itinerant carriers to local magnetic moments [4]. This mechanism results in the current-driven magnetization switching and excitations, which has potential application in terms of magnetic data storage and non-volatile memories. The latter, spin Hall effect, is considered as well to be one of the most fascinating mechanisms in condensed matter physics due to its ability of generating non-equilibrium spin currents without the need for any magnetic materials. In fact the spin Hall effect relies only on the presence of the spin-orbit interaction in order to create an imbalance between the majority and minority spins. The objective of this thesis is to investigate the impact of disorder on spin dependent transport phenomena. To do so, we identified three classes of systems on which such disorder may have a dramatic influence: (i) antiferromagnetic materials, (ii) impurity-driven spin-orbit coupled systems and (iii) two dimensional semiconducting electron gases with Rashba spin-orbit coupling. Antiferromagnetic materials - We showed that in antiferromagnetic spin-valves, spin transfer torque is highly sensitive to disorder, which prevents its experimental observation. To solve this issue, we proposed to use either a tunnel barrier as a spacer or a local spin torque using spin-orbit coupling. In both cases, we demonstrated that the torque is much more robust against impurities, which opens appealing venues for its experimental observation. Extrinsic spin-orbit coupled systems - In disordered metals accommodating spin orbit coupled impurities, it is well-known that spin Hall effect emerges due to spin dependent Mott scattering. Following a recent prediction, we showed that another effect coexists: the spin swapping effect, that converts an incoming spin current into another spin current by "swapping" the momentum and spin directions. We showed that this effect can generate peculiar spin torque in ultrathin magnetic bilayers. Semiconductors spintronics - This last field of research has attracted a massive amount of hope in the past fifteen years, due to the ability of coherently manipulating the spin degree of freedom through interfacial, so-called Rashba, spin-orbit coupling. However, numerical simulations failed reproducing experimental results due to coherent interferences between the very large number of modes present in the system. We showed that spin-independent disorder can actually wash out these interferences and promote the conservation of the spin signal. In the course of this PhD, we showed that while disorder-induced dephasing is usually detrimental to the transmission of spin information, in selected situation, it can actually promote spin transport mechanisms and participate to the enhancement of the desired spintronics phenomenon. Quantum Transport Non-Equilibrium Green's Functions Spintronics Spin Valves Spin Hall Effect Spin Torque
12	Dynamical spin injection in graphene Singh, Simranjeet 01 January 2014 (has links) Within the exciting current trend to explore novel low-dimensional systems, the possibility to inject pure spin currents in graphene and other two-dimensional crystals has attracted considerable attention in the past few years. The theoretical prediction of large spin relaxation times and experimentally observed mesoscopic-scale spin diffusion lengths places graphene as a promising base system for future spintronics devices. This is due to the unique characteristics intrinsic to the two-dimensional lattice of carbon atoms forming graphene, such as the lack of nuclear spins and weak spin-orbit coupling of the charge carriers. Interestingly for some spintronic applications, the latter can be chemically and physically engineered, with large induced spin-orbit couplings found in functionalized graphene sheets. Understanding spin injection, spin current and spin dynamics in graphene is of a great interest, both from the fundamental and applied points of view. This thesis presents an experimental study of dynamical generation of spin currents in macroscopic graphene sheets by means of spin pumping from the precessing magnetization of an adjacent ferromagnet. The spin pumping characteristics are studied by means of ferromagnetic resonance (FMR) measurements in Permalloy/graphene (Py/Gr) bilayers. Changes in the FMR linewidth induced by the presence of graphene (when compared to studies with only Py films) correspond to an increase in the Gilbert damping in the ferromagnetic layer (proportional to the FMR linewidth) and interpreted as a consequence of spin pumping at the Py/Gr interface driven by the Py magnetization dynamics (i.e., magnetic induced by the microwave stimulus). FMR experiments are performed on different FM/Gr interfaces, completing a set of studies designed to systematically identify and eliminate damping enhancement arising from processes other than spin pumping. Remarkably, a substantial enhancement of the Gilbert damping observed in Py/Gr strips with graphene protruding a few micrometers from the strip sides is univocally associated to spin pumping at the quasi-onedimensional interface between the Py strip edges and graphene. This increase in the FMR linewidth compares with observations in other bilayer systems, in where thick (thicker than the spin diffusion length) layers of heavy metals with strong spin-orbit coupling are employed as the non-magnetic layer, indicating that spin relaxation in chemically grown graphene must be greatly enhanced in order to account for the losses of angular momentum lost by the ferromagnet. The fundamental implications of the results presented in this thesis point to a non-trivial nature of the spin pumping mechanism owing to the two-dimensionality of the non-magnetic layer (i.e., graphene). In addition, a spintronics device designed to interconvert charge and spin currents has been designed. A high-frequency microwave irradiation lock-in modulation technique is employed to detect the small electrical voltages generated by the inverse spin Hall effect (ISHE). As a proof of principle, a successful spin-charge interconversion in Py/Pt-based devices is experimentally demonstrated in this thesis. The challenges associated with the spin-charge interconversion in twodimensional devices are discussed and systematically addressed, and a potential device geometry for measuring the ISHE in Py/Gr-based systems is provided. Spin pumping graphene gilbert damping spin charge interconversion inverse spin hall effect ferromagnetic resonance Physics
13	Study on spin-orbit torque effects in metallic bi-layer and single-layer systems / 金属二層及び単層構造におけるスピン軌道トルク効果に関する研究 Aoki, Motomi 25 September 2023 (has links) 付記する学位プログラム名: 京都大学卓越大学院プログラム「先端光・電子デバイス創成学」 / 京都大学 / 新制・課程博士 / 博士(工学) / 甲第24891号 / 工博第5171号 / 新制\|\|工\|\|1987(附属図書館) / 京都大学大学院工学研究科電子工学専攻 / (主査)教授白石誠司, 准教授掛谷一弘, 教授小野輝男, 教授森山貴広 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM Spintronics Spin-orbit torque Magnetoresistive random access memory Spin Hall effect Magnetic material 500
14	Analysis and Applications of Novel Optical Single - and Multi - Layer Structures Li, Han January 2015 (has links) No description available. Optics
15	Efeito Hall de spin em nanoestruturas semicondutoras: rumo à novos dispositivos de spintrônica / Spin Hall effect in semiconductor nanostructures: towards novel spintronic devices Rahim, Abdur 18 June 2015 (has links) Este trabalho apresenta as propriedades de transporte eletrônico de isolantes topológicos bidimensionais (TI) baseados em poços quânticos de HgTe/CdTe. Estas heteroestruturas, no regime de bandas invertido, contem um novo estado conhecido como isolante de spin Hall quântico (QSHI). Este estado apresenta um comportamento de isolante no corpo (bulk), mas exibe estados condutores sem lacunas nas bordas (edges), as quais podem ser verificadas em medidas de transporte. Medidas de resistência de quatro terminais foram observadas perto do valor quantizado em amostras mesoscópicas. No entanto, para amostras com mais de um m, a resistência pode ser muito maiores que h/2e2 devido à presença de defasagem de spin, não homogeneidade ou desordem na amostra. Esta tese aborda o problema da resistência não quantizado observada em amostras macroscópicas de dimensões maiores a algum mícron. Nós relatamos observação e investigação sistemática de transporte local e não local em poços quânticos de HgTe (8.0-8.3 nm) com estrutura de banda invertida correspondente à fase de isolante de spin Hall quântico. O dispositivo MCT1 consiste de três segmentos consecutivos de largura 4 m e de comprimentos diferentes (2 m, 8 m, 32 m), e sete sondas de tensão. O dispositivo MCT2 foi fabricado com um comprimento litográfico de 6 m e largura 5 m. Ambos dispositivos estão equipados com uma porta superior (top gate), que permite ajustar a densidade de portadores do dispositivo. A aplicação de uma tensão de porta muda a densidade de portadores, transformando a condutividade do poço quântico de tipo n para tipo p através de uma fase intermediária chamada de ponto a neutralidade de carga (CNP). Picos acentuados não universais (R >> h/2e2) em ambas as resistividades, local e não local, foram observados próximos ao CNP os quais diminuem rapidamente a medida que se afasta do CNP. Tal comportamento próximo ao CNP pode ser explicado usando o modelo de transporte de bordas (edge) e corpo (bulk), que inclui tanto os estados de borda como o corpo para a contribuição à corrente. O desvio dos valores da resistência de quarto terminais do valor quantizado (R >> h/2e2) em amostras macroscópicas com dimensões acima de algum mícron é um dos principais problemas no campo dos isolantes topológicos. Recentemente foi proposto um modelo por Vayrynen et al., onde tem sido considerado a influência de poças de carga, resultantes de distribuições de carga não homogêneas em isolantes topológicos 2d, na condutância de estados de borda helicoidal. Os estados de borda são acoplados por tunelamento a essas poças metálicas ou pontos quânticos. A permanência dos elétrons em pontos quânticos pode levar a um retroespalhamento inelástico significativo dentro da borda e modifica o transporte balístico. Portanto transporte balístico coerente é esperado somente na região entre poças, e o total de resistência de quatro terminais excede o valor quantizado. Introduzindo as interações elétron-elétron em sistemas de uma dimensão resulta em um liquido de Luttinger (LL). Os estados de borda helicoidais em isolantes topológicos 2d, podem ser tratados como um líquido de Luttinger ideal, uma vez que, naturalmente, aparecem em poços quânticos de HgTe. Entre as várias assinaturas específicas do comportamento do LL, como a dependência da temperatura, é importante se concentrar nas propriedades de não equilíbrio do LL. Em contraste com os líquidos de Fermi convencionais, nenhum estado excitado decairá ao estado de equilíbrio, caracterizado pela temperatura, na ausência de desordem. Medidas de elétron-aquecimento podem ser usadas para entender a física que governa os processos de relaxamento em LL. Nós temos realizado medidas de transporte não linear no CNP em isolantes topológicos 2d de HgTe. Este método, juntamente com a dependência da resistência com a temperatura, pode ser utilizado para determinar o mecanismo de relaxação da energia dos estados de borda helicoidais em QSHI. Nosso experimento falhou em confirmar as assinaturas especificas do comportamento do líquido de Luttinger. No entanto, o efeito de aquecimento de elétron pode ser descrito pelo mecanismo convencional de relaxamento de energia, esperado para espalhamento elétron-fônon. / This thesis present electronic transport properties of two-dimensional topological insulators (TI) based on HgTe/CdTe quantum wells. These heterostructures, in the band inverted regime, hosts a novel state known as the quantum spin Hall insulator. This state is identified as insulator in the bulk, but exhibits gapless conducting states at their edges which can be verified in transport experiments. Four-terminal resistance close to the quantized value has been observed in mesoscopic samples. However, for samples longer than 1 m, the resistance might be much higher than h/2e2 due to the presence of spin dephasing, inhomogeneity or disorder in the sample. This thesis address the problem of non-quantized resistance observed in macroscopic samples of dimensions longer than few microns. We report on the observation and a systematic investigation of local and nonlocal transport in HgTe quantum wells (8.0-8.3 nm) with inverted band structure corresponding to the quantum spin Hall insulating (QSHI) phase. The device MCT1 consists of three 4 m wide consecutive segments of different length (2 m, 8 m, 32 m), and seven voltage probes. The device MCT2 was fabricated with a lithographic length 6 m and width 5 m. Both devices are equipped with a top gate which allows tuning the carrier density of the device. Applying gate bias changes the carrier density transforming the quantum well conductivity from n-type to p-type via an intermediate phase, called the charge neutrality point (CNP). Non-universal (R >> h/2e2) peaks in both local and nonlocal resistivity were observed near the CNP which decreases rapidly going away from CNP. Such a behavior near CNP can be explained using the edge plus bulk transport model, which includes both the edge states and bulk contribution to the total current. Deviation of the four-terminal resistance from quantization (R >> h/2e2) in macroscopic samples, with dimensions above a few microns, is one of the major issue in the field of topological insulators. Recently a model was proposed by Vayrynen et al., where influence of charge puddles, resulting from inhomogeneous charge distribution in 2d topological insulators, on its helical edge conductance has been considered. The edge states are tunnel coupled to these metallic puddles or quantum dots. Electron´s dwelling in the quantum dot may lead to significant inelastic backscattering within the edge and modifies the ballistic transport. Therefore ballistic coherent transport is expected only in the region between the puddles, and the total four-terminal resistance exceeds the quantized value. Introducing electron-electron interactions in one-dimensional systems results in a Luttinger liquid (LL). The helical edge states in 2d topological insulator, can be treated as ideal Luttinger liquid, since it naturally appears in HgTe quantum wells. Among the various specific signatures of the LL behavior, such as temperature dependence, it is important to focus on non-equilibrium properties of LL. In contrast to conventional Fermi liquids, none of the excited state will decay to equilibrium state, characterized by temperature, in the absence of disorder. Electron-heating measurements can be used to understand the physics governing relaxation processes in LL. We have performed non-linear transport measurements at the CNP in HgTe based 2d topological insulators. This method together with temperature dependence of resistance can be used to determine the energy relaxation mechanism of the helical edge modes in QSHI. Our experiments fail to confirm the specific signatures of Luttinger liquid behavior. However, electron heating effect can be described by conventional energy relaxation mechanism, expected for electron-phonon interactions.
16	Efeito Hall de spin em nanoestruturas semicondutoras: rumo à novos dispositivos de spintrônica / Spin Hall effect in semiconductor nanostructures: towards novel spintronic devices Abdur Rahim 18 June 2015 (has links) Este trabalho apresenta as propriedades de transporte eletrônico de isolantes topológicos bidimensionais (TI) baseados em poços quânticos de HgTe/CdTe. Estas heteroestruturas, no regime de bandas invertido, contem um novo estado conhecido como isolante de spin Hall quântico (QSHI). Este estado apresenta um comportamento de isolante no corpo (bulk), mas exibe estados condutores sem lacunas nas bordas (edges), as quais podem ser verificadas em medidas de transporte. Medidas de resistência de quatro terminais foram observadas perto do valor quantizado em amostras mesoscópicas. No entanto, para amostras com mais de um m, a resistência pode ser muito maiores que h/2e2 devido à presença de defasagem de spin, não homogeneidade ou desordem na amostra. Esta tese aborda o problema da resistência não quantizado observada em amostras macroscópicas de dimensões maiores a algum mícron. Nós relatamos observação e investigação sistemática de transporte local e não local em poços quânticos de HgTe (8.0-8.3 nm) com estrutura de banda invertida correspondente à fase de isolante de spin Hall quântico. O dispositivo MCT1 consiste de três segmentos consecutivos de largura 4 m e de comprimentos diferentes (2 m, 8 m, 32 m), e sete sondas de tensão. O dispositivo MCT2 foi fabricado com um comprimento litográfico de 6 m e largura 5 m. Ambos dispositivos estão equipados com uma porta superior (top gate), que permite ajustar a densidade de portadores do dispositivo. A aplicação de uma tensão de porta muda a densidade de portadores, transformando a condutividade do poço quântico de tipo n para tipo p através de uma fase intermediária chamada de ponto a neutralidade de carga (CNP). Picos acentuados não universais (R >> h/2e2) em ambas as resistividades, local e não local, foram observados próximos ao CNP os quais diminuem rapidamente a medida que se afasta do CNP. Tal comportamento próximo ao CNP pode ser explicado usando o modelo de transporte de bordas (edge) e corpo (bulk), que inclui tanto os estados de borda como o corpo para a contribuição à corrente. O desvio dos valores da resistência de quarto terminais do valor quantizado (R >> h/2e2) em amostras macroscópicas com dimensões acima de algum mícron é um dos principais problemas no campo dos isolantes topológicos. Recentemente foi proposto um modelo por Vayrynen et al., onde tem sido considerado a influência de poças de carga, resultantes de distribuições de carga não homogêneas em isolantes topológicos 2d, na condutância de estados de borda helicoidal. Os estados de borda são acoplados por tunelamento a essas poças metálicas ou pontos quânticos. A permanência dos elétrons em pontos quânticos pode levar a um retroespalhamento inelástico significativo dentro da borda e modifica o transporte balístico. Portanto transporte balístico coerente é esperado somente na região entre poças, e o total de resistência de quatro terminais excede o valor quantizado. Introduzindo as interações elétron-elétron em sistemas de uma dimensão resulta em um liquido de Luttinger (LL). Os estados de borda helicoidais em isolantes topológicos 2d, podem ser tratados como um líquido de Luttinger ideal, uma vez que, naturalmente, aparecem em poços quânticos de HgTe. Entre as várias assinaturas específicas do comportamento do LL, como a dependência da temperatura, é importante se concentrar nas propriedades de não equilíbrio do LL. Em contraste com os líquidos de Fermi convencionais, nenhum estado excitado decairá ao estado de equilíbrio, caracterizado pela temperatura, na ausência de desordem. Medidas de elétron-aquecimento podem ser usadas para entender a física que governa os processos de relaxamento em LL. Nós temos realizado medidas de transporte não linear no CNP em isolantes topológicos 2d de HgTe. Este método, juntamente com a dependência da resistência com a temperatura, pode ser utilizado para determinar o mecanismo de relaxação da energia dos estados de borda helicoidais em QSHI. Nosso experimento falhou em confirmar as assinaturas especificas do comportamento do líquido de Luttinger. No entanto, o efeito de aquecimento de elétron pode ser descrito pelo mecanismo convencional de relaxamento de energia, esperado para espalhamento elétron-fônon. / This thesis present electronic transport properties of two-dimensional topological insulators (TI) based on HgTe/CdTe quantum wells. These heterostructures, in the band inverted regime, hosts a novel state known as the quantum spin Hall insulator. This state is identified as insulator in the bulk, but exhibits gapless conducting states at their edges which can be verified in transport experiments. Four-terminal resistance close to the quantized value has been observed in mesoscopic samples. However, for samples longer than 1 m, the resistance might be much higher than h/2e2 due to the presence of spin dephasing, inhomogeneity or disorder in the sample. This thesis address the problem of non-quantized resistance observed in macroscopic samples of dimensions longer than few microns. We report on the observation and a systematic investigation of local and nonlocal transport in HgTe quantum wells (8.0-8.3 nm) with inverted band structure corresponding to the quantum spin Hall insulating (QSHI) phase. The device MCT1 consists of three 4 m wide consecutive segments of different length (2 m, 8 m, 32 m), and seven voltage probes. The device MCT2 was fabricated with a lithographic length 6 m and width 5 m. Both devices are equipped with a top gate which allows tuning the carrier density of the device. Applying gate bias changes the carrier density transforming the quantum well conductivity from n-type to p-type via an intermediate phase, called the charge neutrality point (CNP). Non-universal (R >> h/2e2) peaks in both local and nonlocal resistivity were observed near the CNP which decreases rapidly going away from CNP. Such a behavior near CNP can be explained using the edge plus bulk transport model, which includes both the edge states and bulk contribution to the total current. Deviation of the four-terminal resistance from quantization (R >> h/2e2) in macroscopic samples, with dimensions above a few microns, is one of the major issue in the field of topological insulators. Recently a model was proposed by Vayrynen et al., where influence of charge puddles, resulting from inhomogeneous charge distribution in 2d topological insulators, on its helical edge conductance has been considered. The edge states are tunnel coupled to these metallic puddles or quantum dots. Electron´s dwelling in the quantum dot may lead to significant inelastic backscattering within the edge and modifies the ballistic transport. Therefore ballistic coherent transport is expected only in the region between the puddles, and the total four-terminal resistance exceeds the quantized value. Introducing electron-electron interactions in one-dimensional systems results in a Luttinger liquid (LL). The helical edge states in 2d topological insulator, can be treated as ideal Luttinger liquid, since it naturally appears in HgTe quantum wells. Among the various specific signatures of the LL behavior, such as temperature dependence, it is important to focus on non-equilibrium properties of LL. In contrast to conventional Fermi liquids, none of the excited state will decay to equilibrium state, characterized by temperature, in the absence of disorder. Electron-heating measurements can be used to understand the physics governing relaxation processes in LL. We have performed non-linear transport measurements at the CNP in HgTe based 2d topological insulators. This method together with temperature dependence of resistance can be used to determine the energy relaxation mechanism of the helical edge modes in QSHI. Our experiments fail to confirm the specific signatures of Luttinger liquid behavior. However, electron heating effect can be described by conventional energy relaxation mechanism, expected for electron-phonon interactions.
17	Spin hall effect in paramagnetic thin films Xu, Huachun 15 May 2009 (has links) Spintronics, an abbreviation of spin based electronics and also known as magneto electronics, has attracted a lot of interest in recent years. It aims to explore the role of electrons’ spins in building next generation electric devices. Using electrons’ spins rather than electrons’ charges may allow faster, lower energy cost devices. Spin Hall Effect is an important subfield of spintronics. It studies spin current, spin transport, and spin accumulation in paramagnetic systems. It can further understanding of quantum physics, device physics, and may also provide insights for spin injection, spin detection and spin manipulation in the design of the next generation spintronics devices. In this experimental work, two sets of experiments were prepared to detect the Spin Hall Effect in metallic systems. The first set of experiments aims to extract Spin Hall Effect from Double Hall Effect in micrometer size metal thin film patterns. Our experiments proved that the Spin Hall Effect signal was much smaller than the theoretically calculated value due to higher electrical resistivity in evaporated thin films. The second set of experiments employs a multi-step process. It combines micro fabrication and electrochemical method to fabricate a perpendicular ferromagnet rod as a spin injector. Process description and various techniques to improve the measurement sensitivity are presented. Measurement results in aluminum, gold and copper are presented in Chapters III, IV and V. Some new experiments are suggested in Chapters V and VI. spin hall effect metal lithography electroplate liftoff evaporation thin film low noise measurement spin injection diffusion magnetic
18	Intrinsic anisotropic magnetoresistance in spin-polarized two-dimensional electron gas with Rashba spin-orbit interaction Kato, Takashi, Ishikawa, Yasuhito, Itoh, Hiroyoshi, Inoue, Jun-ichiro 06 1900 (has links) No description available. ballistic transport enhanced magnetoresistance spin Hall effect spin polarised transport spin-orbit interactions two-dimensional electron gas
19	Magnetorresistência e correntes de spin em Multicamadas de Ni81Fe19/ZnO/Pd / Magnetoresistance and spin current in multilayers Ni81Fe19/ZnO/Pd Dugato, Danian Alexandre 02 March 2017 (has links) In this work, we analyzed samples of thin films Ni81Fe19 and Pd with ZnO spacer. Ni81Fe19 is a ferromagnet with a low saturation magnetic field. Pd is a normal metal with high spinorbit coupling, much used in spin Hall effect and inverse spin Hall effect studies. ZnO is a semiconductor whose role is to reduce the charge current between layers. The sample have 5 nm of Ni81Fe19, 3 nm of Pd, and 2 nm of ZnO, with dimensions of 0.4 mm x 8 mm, deposited by magnetron sputtering. Using spin pumping we analyze the signal of the continuous voltage induced by ferromagnetic resonance. These samples the measured signal is a consequence of anisotropic magnetoresistance, anomalous Hall effect and inverse spin Hall effect. The thicknesses used contributes to a predominant inverse spin Hall effect signal. The ZnO spacer layer 2 nm reduces the effects of spin rectification, while maintaining spin current transfer. / Neste trabalho analisamos amostras de filmes finos de Ni81Fe19 e Pd separados por ZnO. O Ni81Fe19 foi escolhido por ser um ferromagneto com baixo campo magnético de saturação. O Pd é um metal normal com alto acoplamento spin-órbita, muito usado em estudos de efeito Hall de spin e efeito Hall de spin inverso. O ZnO é um semicondutor com o papel de diminuir a transferência de corrente de carga entre as camadas. As amostras tem espessura de 5 nm de Ni81Fe19, 3 nm de Pd e 2 nm de ZnO, com dimensões de 0,4 mm x 8 mm, depositadas por magnetron sputtering. Através da técnica de spin pumping analisamos o sinal de tensão contínua induzida por ressonância ferromagnética. Nestas amostras o sinal medido é consequência de efeitos de magnetorresistência anisotrópica, efeito Hall anômalo e efeito Hall de spin inverso. As espessuras utilizadas permitem um sinal de efeito Hall de spin inverso predominante. A camada espaçadora de 2nm de ZnO reduz os efeitos de retificação de spin, mantendo a transferência de corrente de spin. Correntes de spin Efeito Hall de spin inverso Magnetorresistência Spin current Inverse spin Hall effect Magnetoresistance CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA
20	A Study of Electrical Transport and 1 / f Noise in Topological Insulators Bhattacharyya, Semonti January 2016 (has links) (PDF) The recent discoveries of topological insulators (TI) has opened a new realm for study¬ing topological systems and exploring the exotic properties they offer. The in-built topological protection against direct backscattering and absence of localization makes two-dimensional (2D) surface states of bismuth chalcogenide-based strong TI a promising platform for studying interesting phenomena in condensed matter physics like dissipation-less transport, quantum anomalous hall effect, topological magnetoelectric effect, majo¬rana fermions etc. and also makes this system very suitable for applications in the fields of electronics and spintronics. However, realization of these novel states can be diﬃcult because of scattering of surface states from different types of disorders (intrinsic or ex¬trinsic) or the presence of parallel channels in the bulk of the sample which can dominate over surface transport. The main goal of this thesis is to evaluate the performance of TI as an electronic element and look into elastic and inelastic scattering processes and kinetics of these scatterers. In most part of this work we concentrate on the magnitude and origin of low-frequency ﬂicker noise or the 1/f-noise, a key performance marker in electronics, to characterize the electrical transport in TI. In this work we have studied 1/f-noise in both mechanically exfoliated TI-flakes and epitaxially grown TI films by varying chemical potential and temperature. Our study of exfoliated TI-flakes with a wide range of thickness (10 nm to 80 μm) suggests that whereas at thinner (<100 nm) samples and at low temperature (<70 K), the electrical transport happens entirely at the surface, resistance fluctuations in the surface states are mainly caused by potential fluctuations caused by generation-recombination processes in the bulk of TI. Study of 1/f-noise in MBE-grown magnetically doped TI reveals signature of hopping transport through localized bulk mid gap states. These states can either be Cr-impurity band or disorder-induced mobility edge states of bulk valence band. Our study of quantum transport in exfoliated TI-devices indicate presence of a de-coherence mechanism which saturates phase-coherence length and temperature below T< 3 K and results from a unique scattering mechanism caused by localized magnetic moments in these systems Electrical Transport Topological Insulators Quantum Spin Hall Effect Topological Insulator Materials Epitaxial Thin Films TI Films Topological Insulator Films Physics

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