Correlation Between the Structural, Optical, and Magnetic Properties of CoFeB and CoFeB Based Magnetic Tunnel Junctions Upon Laser or Oven Annealing

Sharma, Apoorva

23 April 2021

Diese Dissertation befasst sich mit der Untersuchung der maßgeblichen Herausforderungen der heutigen TMR-Präparation (tunneling magnetoresistance) für beispielsweise Magnetfeldsensor- oder auch Speichertechnologie (MRAM – magnetic random access memory). Im ersten Teil der Arbeit werden die elektronischen, strukturellen und magnetischen Eigenschaften der ferromagnetischen Elektrode eines typischen magnetischen Tunnelkontaktes, z.B. CoFeB, erforscht, wobei spektroskopische Ellipsometrie, magnetooptische Spektroskopie, Röntgendiffraktometrie und Messverfahren für den spezifischen elektrischen Widerstand zum Einsatz kommen. Weiterhin wurde der Einfluss der Temperatur einer thermischen Behandlung auf die optischen und magneto-optischen Merkmale untersucht, wobei eine starke Korrelation zwischen den beobachteten spektralen Merkmalen und der Kristallisation von CoFeB nachgewiesen wurde. Die (magneto-) optische Spektroskopie bietet somit eine zerstörungsfreie und besonders sensitive Validierungsmethode für die Dünnschichtkristallisation, die in die moderne CMOS Herstellungstechnologie integriert werden kann. Der zweite Teil der Arbeit befasst sich mit dem lokalen Tempern unter Verwendung eines fokussierten Laserstrahls, mit dem Ziel die Referenzmagnetisierung in einem magnetischen Tunnelkontakt definiert einzustellen und die Wirkung der hierfür notwendigen thermischen Behandlung auf die übrigen Schichten im Schichtstapel zu untersuchen. Hierzu wurden zahlreiche Parameter für das laserbasierte lokale Tempern variiert, um die optimale Austauschfeldstärke im magnetischen Referenzsystem einzustellen, idealerweise ohne den gegebenen Schichtstapel zu schädigen. Schließlich wurde der Einfluss des laserbasierten Temperns (als auch des Ofentemperns) auf die Unversehrtheit der Schichten und Grenzflächen, insbesondere auf die Diffusion verschiedener Elemente, mittels Röntgen-Photoemissionsspektroskopie untersucht.

info:eu-repo/classification/ddc/530

ddc:530

Ultraschnelle Ladungsträger- und Spindynamik in II-VI und III-V Halbleitern mit weiter Bandlücke

Raskin, Maxim

10 October 2013

Die vorliegende Arbeit beschäftigt sich mit der Herstellung und Charakterisierung von verdünnten magnetischen II-VI und III-V Halbleiter-Dünnschichten. Diese Systeme bieten vereinfachte optische kohärente Kontrolle von Spin-basierten Prozessen und eignen sich hervorragend für den Einsatz in zukünftigen opto-magnetischen Anwendungen. ZnO-, ZnXO-, GaN- und GaXN-Proben (X = Mangan, Cobalt) sind mit Hilfe der naßchemischen Sol-Gel Synthese hergestellt worden. Sie werden mit Hilfe der Photolumineszenzspektroskopie untersucht. Die spektrale Position der elektronischen Niveaus in der Nähe der Bandkante dieser Materialien wird bestimmt, um in weiteren Experimenten die freien und gebundenen Exzitonen einzeln abzufragen. Mit der Methode der zeitaufgelösten differentiellen Transmissionsspektroskopie (TRDT) werden die Lebensdauern dieser Ladungsträger bestimmt und mit ultraschnellen Prozessen der optischen Anregung und Relaxation in Verbindung gebracht. Die Methode der zeitaufgelösten Faraday-Rotation-Spektroskopie (TRFR) wird angewandt, um die kohärente Spindynamik des optisch angeregten Teilchenensembles zu beschreiben. Die Kohärenz unterliegt den Störeinflüssen verschiedener Streumechanismen, die in der vorliegenden Arbeit identifiziert und quantitativ beschrieben werden. Bei einigen untersuchten Materialsystemen (ZnCoO, ZnMnO und GaMnN) wird die jeweilige spezifische Elektron-Ion Austauschenergie N0α bestimmt, welche die Kopplungsstärke der elektronischen Spins zu denen der Dotierionen beschreibt.

info:eu-repo/classification/ddc/540

ddc:540

Spintronik; Halbleiter

Micromagnetic Study of Current Induced Domain Wall Motion for Spintronic Synapses

Petropoulos, Dimitrios-Petros

January 2021

Neuromorphic computing applications could be made faster and more power efficient by emulating the function of a biological synapse. Non-conventional spintronic devices have been proposed that demonstrate synaptic behavior through domain wall (DW) driving. In this work, current induced domain wall motion has been studied through micromagnetic simulations. We investigate the synaptic behavior of a head to head domain wall driven by a spin polarized current in permalloy (Py) nanostrips with shape anisotropy, where triangular notches have been modeled to account for edge roughness and provide pinning sites for the domain wall. We seek optimal material parameters to keep the critical current density for driving the domain wall at order 1011 A/m2.

computational physics

micromagnetism

micromagnetic simulations

Mumax3

current induced domain wall motion

domain wall driving

spin current

spin transfer torque

synapse

memristor

Neuromorphic computing

spintronic

brain inspired computing

Permalloy

nanowire

nanostrip

notches

Other Physics Topics

Annan fysik

INFRARED DIGITAL-MODE POISSONIAN BOLOMETER

Leif Harrison Bauer (18863617)

24 June 2024

<p dir="ltr">The market for infrared detectors has grown significantly in recent years due to the wide variety of applications from astronomy to medical thermography. Additionally, several emerging applications for high-speed infrared technologies are in development such as infrared LIDAR, autonomous vehicles, semiconductor device analysis, and free space communication. Improvements in the readout-speed and sensitivity of uncooled infrared detectors are required for some of these applications, and have been a long-standing goal in the field. Two technologies currently dominate the detection of infrared radiation, photodiodes and bolometers. Bolometers are extremely interesting as they are currently the most sensitive infrared detectors (either cooled or uncooled). We will propose and demonstrate a new type of bolometric infrared detector based on a highly structured spintronic material. The device's detection mechanism utilizes thermally activated magnetic transitions in a nanoscale magnetic device. We will also discuss a classification for detectors based on their digital-mode (discrete) or analog (continuous) readout signals. We develop a stochastic model to compare the sensitivity of these detectors. From this model we demonstrate several fundamental limits in the measurement of temperature by infrared detection.</p>

Magnetism and palaeomagnetism

Electronic sensors

Nanoelectronics

Nanophotonics

spintronic devices

stochastic devices

infrared detectors

bolometers

Poissonian

magnetic tunnel junction

MTJ

SUN

nanoscale detectors

Investigação teórica de materiais multiferróicos

Ribeiro, Renan Augusto Pontes

26 February 2019

Submitted by Angela Maria de Oliveira (amolivei@uepg.br) on 2019-03-14T19:25:14Z No. of bitstreams: 2 license_rdf: 811 bytes, checksum: e39d27027a6cc9cb039ad269a5db8e34 (MD5) Renan Augusto Pontes Ribeiro.pdf: 9570923 bytes, checksum: a291ba63c045a11cb0a642a480367e27 (MD5) / Made available in DSpace on 2019-03-14T19:25:14Z (GMT). No. of bitstreams: 2 license_rdf: 811 bytes, checksum: e39d27027a6cc9cb039ad269a5db8e34 (MD5) Renan Augusto Pontes Ribeiro.pdf: 9570923 bytes, checksum: a291ba63c045a11cb0a642a480367e27 (MD5) Previous issue date: 2019-02-26 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / O desenvolvimento da spintrônica tem motivado a busca por novos materiais multiferróicos devido à multifuncionalidade desses compostos associada ao acoplamento entre diferentes ordens ferróicas em uma estrutura cristalina. No presente estudo, propomos a investigação teórica, baseada na Teoria do Funcional de Densidade, dos materiais ATiO3 (A = Mn, Fe, Ni) na estrutura R3c com objetivo de esclarecer o efeito da substituição do cátion A sobre as propriedades estruturais, magnéticas e eletrônicas, bem como descrever diferentes mecanismos de controle das propriedades multiferróicas baseados em arquiteturas de filmes-finos, morfologia e controle de defeitos intrínsecos. Para uma maior compreensão dos efeitos envolvidos nos materiais ATiO3, diferentes funcionais de troca e correlação foram investigados e o funcional PBE0 apresentou os menores desvios, consequentemente, a melhor representação comparado aos resultados experimentais. Com objetivo de investigar as propriedades conectadas a filmes-finos dos materiais ATiO3, propomos uma metodologia inovadora que permite descrever as deformações uni- e biaxial que se originam na região de interface entre o filme e o substrato. Nesse caso, os resultados obtidos indicam que as distorções estruturais induzem uma transição magnética para o NiTiO3, originando ordenamento ferromagnético a partir de um critério magneto-estrutural associado a deformação dos clusters [MO6] que reproduz satisfatoriamente os resultados experimentais reportados na literatura. De modo análogo, para elucidar a relação entre o magnetismo e a morfologia dos materiais ATiO3, combinamos cálculos de Energia de Superfície, Construção de Wulff e um formalismo avançado para descrever o magnetismo superficial considerando a existência de spins não compensados ao longo dos planos polares (100), (001), (101), (012), (111) e apolares (110). Os resultados indicam que a redução do número de coordenação dos metais A e Ti para os planos (001) e (111) resulta na transferência de carga entre os cátions A2+ e Ti4+, originando espécies Ti3+ magnéticas que aumentam o magnetismo superficial ao longo desses planos. Além disso, esse efeito é capaz de induzir uma alteração do caráter eletrônico para esses materiais, permitindo indicar que a clivagem das superfícies contribui para o controle das propriedades eletrônicas, reduzindo o valor de band-gap ou gerando comportamento meio-metálico. Os mapas morfológicos obtidos indicam que o controle da exposição majoritária do plano (001) para obtenção de discos hexagonais induz um aumento do magnetismo superficial para os materiais ATiO3 em acordo com resultados experimentais, além de predizer diferentes morfologias acessíveis com interessantes propriedades magnéticas. Ademais, o efeito de defeitos intrínsecos como vacâncias de oxigênio no bulk e superfície apolar (110) dos materiais ATiO3 foi investigado indicando que a redução do número de coordenação na região do defeito induz que os elétrons remanescentes sejam localizados, principalmente, nos orbitais 3d vazios dos cátions Ti vizinhos, gerando espécies [TiO5]ꞌ e [TiO4]ꞌ (3d1 ) que possibilitam uma interação ferromagnética nos materiais MnTiO3 e FeTiO3. A combinação entre os diferentes mecanismos investigados permitiu estabelecer um guia científico para o estudo teórico de materiais multiferróicos, contribuindo para descrever as potencialidades dos diferentes materiais bem como predizer novos candidatos. / The development of spintronic has motivated the search for new multiferroic materials due to the multifunctionality of these materials that are associated with the coupling of different ferroic orders into a single crystalline structure. In the present study, we propose a theoretical investigation, based on Density Functional Theory, of ATiO3 (A = Mn, Fe, Ni) materials in the R3c structure in order to clarify the effect of A-site cation replacement on the structural, magnetic and electronic properties, as well as to describe a different mechanism to control the multiferroic properties based on thin-film architectures, morphology and point defects. For a more comprehensive overview of the main effects involved on the ATiO3 materials several exchange-correlation functionals were investigated, being the PBE0 the functional with smallest deviations and, consequently, the best representation in comparison to the experimental results. Aiming to describe the main fingerprints related with the creation of ATiO3 thin-films, we propose an innovative methodology that allows to describe the uniaxial and biaxial deformations originated in the interface region between the film and the substrate. In this case, the results indicate that structural distortions induce a magnetic transition for the NiTiO3, originating ferromagnetic ordering from magneto-structural criteria, which is associated to the deformation of the [MO6] clusters that reproduces satisfactorily the experimental results reported in the literature. Similarly, in order to elucidate the relationship between the magnetism and the morphology of the ATiO3 materials, we combined Surface Energy, Wulff Construction, and an advanced formalism to describe surface magnetism by considering the existence of uncompensated spins along the polar planes (100), (001), (101), (012), (111) and non-polar (110). The results indicate that the reduction of the coordination for both A and Ti metals along the (001) and (111) planes induces a charge transfer between the A 2+ and Ti4+ cations, resulting in magnetic Ti3+ species that increase the superficial magnetism along such planes. Moreover, this effect allowed a change in the electronic structure for these materials, allowing to point out that the cleavage of the surfaces contribute to the control of the electronic properties reducing the band-gap value or generating half-metallic behavior. The morphological maps indicated that the control of the major exposure for the (001) surface to obtain hexagonal discsinduces an increase of the superficial magnetism for the ATiO3 materials according to experimental results, besides predicting different accessible morphologies with interesting magnetic properties. In addition, the effect of intrinsic defects such as oxygen vacancies on the bulk and non-polar (110) surface of the ATiO3 materials were investigated, indicating that the reduction of coordination in the defect region induces the localization of the remaining electrons in the empty 3d orbitals of neighboring Ti cations, generating [TiO5]'and [TiO4]' (3d1 ) species that allow a ferromagnetic interaction for MnTiO3 and FeTiO3 materials. The combination of the different mechanisms investigated has allowed to stablish a scientific guide for the theoretical study of multiferroic materials, contributing to describe the potentialities of the different materials as well as to predict new candidates.

Teoria do Funcional de Densidade

DFT

Funcionais de troca-correlação

PBE0

R3c

Spintrônica

Multiferróico

Magnetismo

Morfologia

Defeitos pontuais

Conexão Intermetálica

Meio-Metálicos

Density Functional Theory

DFT

Exchange-correlation functionals

PBE0

R3c

Spintronic

Multiferroic

Magnetism

Morphology

Point defects

Intermetallic Connection

Half-Metals

Electronic and magnetic properties of hybrid interfaces : from single molecules to ultra-thin molecular films on metallic substrates / Propriétés électroniques et magnétiques d'interfaces hybrides : des molécules isolées aux films moléculaires ultra-minces sur des substrats métalliques

Gruber, Manuel

28 November 2014

Comprendre les propriétés des interfaces molécules/métaux est d’une importance capitale pour la spintronique organique. La première partie porte sur l’étude des propriétés magnétiques de molécules de phtalocyanine de manganèse. Nous avons montré que les premières couches moléculaires forment des colonnes avec un arrangement antiferromagnétique sur la surface de Co(100). Ces dernières mènent à de l’anisotropie d’échange. La seconde partie porte sur l’étude d’une molécule à transition de spin, la Fe(phen)2(NCS)2, sublimée sur différentes surfaces. Nous avons identifié les états de spin d’une molécule unique sur du Cu(100). De plus, nous avons commuté l’état de spin d’une molécule unique pourvu qu’elle soit suffisamment découplée du substrat. / Understanding the properties of molecules at the interface with metals is a fundamental issue for organic spintronics. The first part is devoted to the study of magnetic properties of planar manganese-phthalocyanine molecules and Co films. We evidenced that the first molecular layers form vertical columns with antiferromagnetic ordering on the Co(100) surface. In turn, these molecular columns lead to exchange bias. The second part is focused on the study of a spin-crossover complex, Fe(phen)2(NCS)2 sublimed on different metallic surfaces. We identified the two spin states of a single molecules on Cu(100). By applying voltages pulses, we switched the spin state of a single molecule provided that it is sufficiently decoupled from the substrate.

Spintronique organique

Transition de spin

Phtalocyanine

Fe(phen)2(NCS)2

Couplage d’échange

Spinterface

Effet Kondo

Microscopie à effet tunnel

Organic spintronic

Spin crossover

Phthalocyanine

Fe(phen)2(NCS)2

Exchange bias

Interlayer exchange coupling

Spinterface

Kondo effect

X-ray absorption spectroscopy

Scanning tunneling microscopy

X-ray magnetic circular dichroism

539.6