Optimisation de jonctions tunnel magnétiques pour STT-MRAM et développement d'un nouveau procédé de nanostructuration de ces jonctions / Engineering of magnetic tunnel junction stacks for improved STT-MRAM performance and development of novel and cost-effective nano-patterning techniques

Chatterjee, Jyotirmoy

29 March 2018

Le but de la thèse sera d'étudier la faisabilité d'un nouveau procédé de nanostructuration des jonctions tunnel de dimension sub-30nm récemment imaginé et breveté par Spintec et le LTM et de tester les propriétés des jonctions tunnel obtenus sur les plans structural, magnétique et des propriétés électriques. Une attention particulière sera mise sur la caractérisation des défauts générés en bord de piliers lors de la gravure des jonctions tunnels et l'impact de ces défauts sur les propriétés magnétiques et de transport. Une autre partie de la thèse concerne l'optimisation des propriétés magnétiques et de transport des empilements jonctions tunnel magnétiques en vue d'en améliorer la stabilité thermique, l'amplitude de magnétoresistance tunnel et la facilité de gravure de l'empilement.En particulier l'insertion de nouveaux matériaux réfractaires (W, ) dans les empilements a été étudiée pour améliorer la stabilité de l'empilement lors des recuits à haute température. Des améliorations ont également été apportées pour renforcer la stabilité de la couche de référence de la jonction tunnel lorsque cette dernière est située au dessus de la barrière tunnel. Par ailleurs, une nouvelle couche de couplage antiferromagnétique a été mise au point permettant de réduire significativement l'épaisseur totale de l'empilement et par là même facilitant sa gravure.Tous ces résultats ont été obtenus par des mesures magnétiques et de transport réalisées sur les couches continues et sur des piliers de taille nanométriques. / The first aim of the thesis is to study the feasibility of a new process for nanopatterning of sub-30nm diameter tunnel junctions recently patented by Spintec and LTM and to test the properties of tunnel junctions obtained, from the point of view of magnetic and electrical properties. Particular attention will be paid on the characterization of defects generated at the pillar edges when patterning the tunnel junctions and the impact of these defects on the magnetic and transport properties. Another part of the thesis is focused on improving the magnetic and transport MTJ stacks with higher thermal budget tolerance. As a part of this, new materials (W, etc) were used as cap layer or as a spacer layer in composite free layer of pMTJ stacks. Moreover, different magnetic materials combined with different non-magnetic spacer have been investigated to improve the thermal stability factor of the composite storage layers. Detailed structural characterizations were performed to demonstrate the improvements in magnetic and electrical properties. A new RKKY coupling layer was found which allowed to obtain an extremely thin pMTJ stack by reducing the SAF layer thickness to 3.8nm. Seed lees multilayers with enhanced PMA is necesssary to realize a top-pinned pMTJ stack which is necessary to configure a spin-orbit torque MRAM (SOT-MRAM)stack and double magnetic tunnel junction stacks (DMTJs). A new seed less multilyar with enhanced PMA and subsequently advanced stacks such as conventional-DMTJ, thin-DMT, SOT-MRAM stacks, Multibit memory were realized. Finally, electrical properties patterned memory devices were also studied to correlate with the magnetic properties of thin films.

Jonctions tunnels magnétiques

Mram

Nanostructuration

Variabilité

Magnétorésistance tunnel

Anisotropie perpendiculaire

Magnetic tunnel junctions

Mram

Nanopatterning

Variability

Tunnel magnetoresistance

Perpendicular anisotropy

530

620

Návrh parkovišť u městského krematoria Ústředního hřbitova v Brně / Design of parking place in crematorium of Brno cemetry

Podhorná, Iva

January 2013

The subject of this thesis is to solve the problem of the lack of the parking places at the city crematorium of the Central Cemetery of Brno. The main task is to deploy the parking lots on the northern and western side of the Central Cemetery. The parking lot on the western side should take into consideration the proposal for a new entrance from this side. This thesis also includes solutions for wheelchair access and for building a new bus stop.

Most přes železniční trať / Bridge over railway line

Drašková, Tereza

January 2013

Subject of this master-thesis is perpendicular bridging over „railway “ČD Břeclav – Přerov v km 180,287 033.Its content is the design of the construction of the bicameral multipole concrete bridge. The chosen option is formed by two additionally prestressed chambers connected by slab. The total length of 10-pin bridge is 307,20 metres. The calculation of effects of the load is done by software NEXIS. The assessment of construction is done manually according to standard ČSN-EN 1992-1-1. The calculation is done including time analysis.

Half-metal magnets Heusler compounds for spintronics / Les alliages d’Heusler demi-métaux magnétiques pour l’électronique de spin

Guillemard, Charles

17 October 2019

L'amélioration des techniques de dépôts et l’évolution de la compréhension de la physique de la matière condensée a conduit à la découverte de phénomènes nouveaux en électronique de spin (spintronique). En particulier, le retournement de l’aimantation par couple de transfert de spin et couple spin-orbite, ainsi que le développement de dispositifs basés sur la propagation d’ondes de spin ont fait de l’amortissement magnétique de Gilbert un paramètre central pour les futures technologies de stockage et de traitement de l’information. Dans cette étude, la prédiction de valeurs très faibles d’amortissement dans les alliages d’Heusler demi métaux magnétiques Co2MnZ est expérimentalement observée et directement corrélée à la structure électronique sous-jacente. En effet, en substituant l’élément Z dans des couches minces monocristallines de haute qualité de Co2MnZ (Z= Al, Si, Ga, Ge, Sn, Sb) faites par épitaxie par jet moléculaire, les propriétés électroniques telles que le gap de spin minoritaire, la position du niveau de Fermi et la polarisation en spin peuvent être accordées et leurs conséquences sur la dynamique de l’aimantation sont analysées. Les résultats expérimentaux nous permettent de comprendre la relation existante entre la structure électronique mesurée et la valeur d’amortissement magnétique, ainsi que de les comparer aux calculs ab initio. Les valeurs d’amortissement entre 4.1 x10-4 et 9 x10-4 pour Co2MnSi, Co2MnGe, Co2MnSn et Co2MnSb sont les plus petites valeurs jamais reportées pour des couches conductrices et constituent une preuve expérimentale qui confirme les prédictions théoriques sur ces alliages d’Heusler demi métaux magnétiques. Ensuite, la relation entre l’amortissement magnétique de Gilbert et le temps de désaimantation ultra-rapide induit par pulse laser dans la série d’alliages quaternaires Co2MnSixAl1-x à polarisation en spin variable est étudiée. Cette partie vise à vérifier des modèles théoriques qui essaient d’unifier ces deux quantités vivant sur des échelles de temps différentes. Finalement, les propriétés structurales et magnétiques de super réseaux Mn3Ga/Co2YZ sont étudiées dans le but de combiner un amortissement de Gilbert très faible, un gap de spin minoritaire ainsi que l’aimantation perpendiculaire aux plans des couches, une caractéristique indispensable pour des dispositifs à faible consommation d’énergie. / Improvements in thin film elaboration methods and a deeper understanding of condensed matter physics have led to new exciting phenomena in spin electronics (spintronics). In particular, magnetization reversal by spin-orbit and spin-transfer torque as well as the development of spin waves based devices have placed the Gilbert magnetic damping coefficient as a key parameter for future data storage and information processing technologies. The prediction of ultralow magnetic damping in Co2MnZ Heusler half-metal magnets is explored in this study and the damping response is shown to be linked to the underlying electronic structure. By substitution of the Z element in high quality Co2MnZ (Z=Al, Si, Ga, Ge, Sn and Sb) epitaxial thin films grown by molecular beam epitaxy, electronic properties such as the minority-spin band gap, Fermi energy position in the band gap, and spin polarization can be tuned and the consequences for magnetization dynamics analyzed. Experimental results allow us to directly explore the interplay of spin polarization, spin gap and Fermi energy position, with the magnetic damping obtained in these films (together with predictions from ab initio calculations). The ultralow magnetic damping coefficients measured in the range from 4.1 x10-4 to 9 x10-4 for Co2MnSi, Co2MnGe, Co2MnSn and Co2MnSb are the lowest values ever reported in conductive layers and offer a clear experimental demonstration of theoretical predictions on half metal magnetic Heusler compounds. Then, the relation between the Gilbert damping and the ultrafast demagnetization time in quaternary Co2MnSixAl1-x compounds with a tunable spin polarization is analyzed. This way, it is possible to confront theoretical models unifying those two quantities that live in different timescales. Finally, structural and magnetic properties of Mn3Ga/Co2YZ Heusler superlattices are investigated in order to combine ultralow Gilbert damping coefficient, minority spin band gap and perpendicularly magnetized heterostructures, another requirement for low energy consumption devices. Through the present work, we aim to prove that Heusler compounds provide an excellent playground to study fundamental magnetism and offer a pathway for future materials design.

Spintronique

Alliages d'Heusler

Demi métaux magnétiques

Amortissement de Gilbert

Anisotropie perpendiculaire

Dynamique ultrarapide

Spintronics

Heusler

Half metal magnets

Gilbert damping

Perpendicular anisotropy

Ultrafast dynamics

620.112 95

621.381

538.302 12

Synthetic Ferrimagnets and Magneto-Plasmonic Structures for Ultrafast Magnetization Switching

Bradlee K Beauchamp (9026657)

25 June 2020

<div>The response time of magnetization switching in current spintronic devices is limited to nanosecond timescales due to the precessional motion of the magnetization during reversal. To overcome this limit two routes of investigation leading to novel recording and logic devices are considered in this thesis: 1) Magnetic tunnel junction structures where the recording and reference layers are replaced by synthetic ferrimagnets and switching is induced by spin transfer torque and 2) Hybrid magneto-photonic devices where switching is induced by plasmon-enhanced all-optical switching. To circumvent limitations of the materials and magnetic properties of CoFeB, the most utilized alloy in spintronics, hcp-CoCrPt, a material that exhibits superior perpendicular anisotropy and thermal stability, is chosen as the ferromagnetic electrode in this work. Whereas actual devices based on the two schemes aforementioned are still in the process of being fabricated, through collaborative work with our international collaborators, this thesis describes fundamental magnetic and structural characterization needed for the realization of said ultrafast switching devices. The magnetic switching behavior of CoCrPt-Ru-CoCrPt synthetic ferrimagnets with perpendicular magnetic anisotropy have been studied in the temperature range from 2K to 300K. It was found that two sets of magnetic transitions occur in the CoCrPt-Ru-CoCrPt ferrimagnet systems studied. The first set exhibits three magnetization states in the 50K – 370K range, whereas the second involves only two states in the 2K and 50K range. The magnetic hysteresis curves of the synthetic ferrimagnet are assessed using an energy diagram technique which accurately describes the competition between interlayer exchange coupling energy, Zeeman energy, and anisotropy energy in the system. This energy diagram analysis is then used to predict the changes in the magnetic hysteresis curves of the synthetic ferrimagnet from 200K to 370K. This represents the potential operation temperature extrema that a synthetic ferrimagnet could be expected to operate at, were it to be utilized as a free layer in a memory or sensor spintronic device in the device configuration described in this dissertation.</div><div>Circularly polarized fs laser pulses generate large opto-magnetic fields in magnetic materials, through the inverse Faraday effect. These fields are attributed to be largely responsible for achieving ultrafast all-optical magnetization switching (AOS). All experimental demonstrations of AOS thus far have been realized on thin films over micron-sized irradiated regions. To achieve magnetization switching speeds in the ps and potentially fs time regimes, this work proposes the use of surface plasmon resonances at the interface of hybrid magneto-photonic heterostructures. In addition to the ability of plasmon resonances to confine light in the nm scale, the resonant excitation can largely enhance induced opto-magnetic fields in perpendicular magnetic anisotropy materials. This requires strong spin-photon coupling between the plasmonic and the magnetic materials, which thus requires the minimization of seed layers used for growth of the magnetic layer. This work reports on the development of ultrathin (1 nm thick) interlayers to control the growth orientation of hcp-Co alloys grown on the refractory plasmonic material, TiN, to align the magnetic axis out-of-plane. CoCrPtTa seed layers down to 1 nm were developed to seed the growth of CoCrPt, and the dependence of the quality of the CoCrPt is investigated as Ta composition is varied in the seed layer. Whereas bismuth iron garnet (BIG) meets the magneto-optical requirements for a hybrid magneto-photonic material, its magnetic and structural properties are highly sensitive to the Bi:Fe ratio and must be grown epitaxially on single crystalline substrates. Therefore, in this work we have investigated alternative materials that offer superior magnetic properties and are amenable to growth on inexpensive substrates. Opto-magnetic field enhancements up to 2.6x in Co-ferrite magneto-photonic heterostructures have been obtained via finite element analysis modelling. Alternative materials for plasmon-enhanced all-optical switching such as Co/Pd multilayers have also been investigated. Successful growth of Co/Pd multilayers on TiN using ultrathin Ti interlayers has been achieved. </div><div><br></div>

synthetic ferrimagnet

magnetic films

CoCrPt

interlayer exchange coupling

perpendicular magnetic recording

magnetic switching

spintronics

magnetic tunnel junctions

plasmonics

nanophotonics

inverse Faraday effect

Etude des effets d'interfaces sur le retournement de l'aimantation dans des structures à anisotropie magnétique perpendiculaire / Study of Interface Effects on Magnetization Reversal in Magnetic Structures with Perpendicular Magnetic Anisotropy

Zhao, Xiaoxuan

06 December 2019

Les mémoires MRAM (Magnetic Random Access Memory) sont l’une des technologies émergentes visant à devenir un dispositif de mémoire «universelle» applicable à une grande variété d’applications. La combinaison du couple de spin-orbite (SOT) résultant de l’effet Hall de spin (SHE) et de l’interaction de Dzyaloshinskii – Moriya (DMI) aux interfaces entre un métal lourd et une couche ferromagnétique s’est révélée être un mécanisme efficace pour induire une propagation de parois magnétiques chirales à des faibles densité de courant. Les dispositifs à parois magnétiques devraient constituer la prochaine génération de supports d’information en raison de leur potentiel pour des densités de stockage très élevées. Cependant, une limitation cruciale est la présence de défauts structuraux qui piègent les parois magnétiques et induisent des courants de seuil élevés ainsi que des effets stochastiques importants. L’origine du piégeage résulte de la présence de défauts structuraux aux interfaces entre la couche magnétique ultra-mince et les autres couches (isolants et/ou métaux lourds) qui induisent une distribution spatiale des propriétés magnétiques comme l’anisotropie magnétique perpendiculaire (PMA) ou le DMI. Comprendre l’influence de la structure des interfaces sur la propagation de parois et sur le DMI en particulier est cruciale pour la conception de futurs dispositifs basse consommation. C’est dans ce contexte très novateur que mon doctorat s’est focalisé sur la manipulation de la structure des interfaces dans des couches ultra-minces à anisotropie magnétique perpendiculaire. Des structures de CoFeB-MgO ont été utilisées afin de mieux comprendre l'impact de la structure des interfaces sur l’anisotropie, le DMI, la propagation de parois et les phénomènes de SOT. L’approche innovante que nous avons utilisée est basée sur l’irradiation par des ions légers pour contrôler le degré de mélange aux interfaces. Sous l’effet du mélange induit par l’irradiation, nous avons observé dans des structures de W-CoFeB-MgO une forte augmentation de la vitesse de parois dans le régime de creep, compatible avec une réduction de la densité des centres de piégeage. Nous avons aussi démontré que l'anisotropie de l'interface Ki et le DMI mesuré par propagation asymétrique de parois se comportent de la même façon en fonction du mélange aux interfaces. Finalement, nous avons fabriqué des barres de Hall afin de mesurer la commutation de l’aimantation induite par SOT. Le centre des croix de Hall a été irradié afin de diminuer localement l’anisotropie. Nous avons observé une réduction de 60% de la densité de courant critique après l’irradiation correspondant au retournement des croix de Hall irradiés par propagation de parois. Notre étude fournit de nouvelles pistes concernant le développement de mémoires magnétiques à faible consommation, de dispositifs logiques et neuromorphiques. / Magnetic Random Access Memory (MRAM), as one of the emerging technologies, aims to be a “universal” memory device for a wide variety of applications. The combination of the spin orbit torque (SOT) resulting from the spin Hall effect (SHE) and the Dzyaloshinskii–Moriya interaction (DMI) at interfaces between heavy metals and ferromagnetic layers has been demonstrated to be a powerful mean to drive efficiently domain-wall (DW) motion, which are expected to be the promising next generation of information carriers owing to ultra-low driving currents and ultra fast DW motion. However, the crucial limitation of SOT induced domain wall motion results from the presence of pinning defects that can induce large threshold currents and stochastic behaviors. Such pinning defects are strongly related to structural inhomogeneities at the interfaces between the ultra-thin ferromagnetic layer and the other materials (insulator and/or heavy metals) that induce a spatial distribution of magnetic properties such as perpendicular magnetic anisotropy (PMA) or DMI. Therefore, understanding the role of the interface structure on DW motion and DMI is crucial for the design of future low power devices.It is under this innovative context that my Ph.D. research has focused on the manipulation of interface structure in ultra-thin magnetic films with perpendicular magnetic anisotropy. CoFeB-MgO structures have been used in order to understand the impact of interface structure on anisotropy, DMI, domain wall motion and SOT phenomena. The innovative approach we have used in this PhD research is based on light ion irradiation to control the degree of intermixing at interfaces. In W-CoFeB-MgO structures with high DMI, we have observed a large increase of the DW velocity in the creep regime upon He⁺ irradiation, which is attributed to the reduction of pinning centres induced by interface intermixing. Asymmetric in-plane field-driven domain expansion experiments show that the DMI value is slightly reduced upon irradiation, and a direct relationship between DMI and interface anisotropy is demonstrated. Using local irradiated Hall bars in SOT devices, we further demonstrate that the current density for SOT induced magnetization switching through DW motion can be significantly reduced by irradiation. Our finding provides novel insights into the development of low power spintronic-memory, logic as well as neuromorphic devices.

Couple de spinorbite

Parois magnétiques

Irradiation

Interfaces

Anisotropie magnétique perpendiculaire

Spintronique

Perpendicular magnetic anisotropy

Spin-Orbit torque

Interface

Irradiation

Magnetic domain wall

Spintronics

Couches minces en Fe-N élaborées par implantation ionique : propriétés structurales et magnétiques / Fe-N thin films made by ion implantation : structural and magnetic properties

Garnier, Louis-Charles

06 May 2019

Les phases alpha'-Fe8N1-x et alpha''-Fe16N2 ont un fort potentiel d’application, en raison de leur anisotropie magnétocristalline uniaxiale et de leur grande aimantation à saturation. Cependant, les valeurs annoncées pour ces propriétés magnétiques restent sujettes à discussion. Les recherches menées au cours de cette thèse de doctorat ont été initiées dans le but de clarifier cette situation. L’élaboration des échantillons a principalement consisté en l’implantation ionique d’azote dans des couches minces de fer alpha épitaxiées sur ZnSe/GaAs (001). Entre autres, les effets de la température de la cible et de la fluence sur la structure cristalline des échantillons ont été analysés par diffractométrie des rayons X. La présence d’une anisotropie magnétique perpendiculaire a été mise en évidence dans les couches minces contenant les phases alpha'-Fe8N1-x ou alpha''-Fe16N2. La constante d’anisotropie a été évaluée par magnétométrie à échantillon vibrant et résonance ferromagnétique. À l’occasion de ces recherches, des domaines en rubans faibles ont été observés par microscopie à force magnétique dans certaines couches minces en Fe-N. Ceux-ci sont particulièrement rectilignes et des dislocations coin se trouvent au sein de leur structure périodique. Des études ont alors été réalisées dans le but de contrôler avec précision la réorientation des domaines en rubans et le déplacement des dislocations magnétiques, à l’aide d’un champ magnétique. / The alpha'-Fe8N1-x and alpha''-Fe16N2 phases have a high potential of application, because of their uniaxial magnetocrystalline anisotropy and their large saturation magnetization. However, the values announced for these magnetic properties remain a subject of discussion. The research conducted during this PhD thesis was initiated in order to clarify this situation. Sample making consisted mainly of nitrogen ion implantation into alpha-Fe thin films, epitaxially grown on ZnSe/GaAs (001). Among others, the effects of target temperature and fluence on the crystal structure of the samples were analyzed by X-ray diffractometry. The presence of a perpendicular magnetic anisotropy was demonstrated in the thin films containing the alpha'-Fe8N1-x and alpha''-Fe16N2 phases. The anisotropy constant was evaluated by vibrating sample magnetometry and ferromagnetic resonance. In this research, weak stripe domains were observed by magnetic force microscopy in some Fe-N thin films. These are particularly straight and edge dislocations are found within their periodic structure. Studies were then carried out to precisely control the reorientation of the stripe domains and the displacement of the magnetic dislocations, using a magnetic field.

Couches minces ferromagnétiques

Anisotropie magnétique perpendiculaire

Domaines en rubans faibles

Implantation ionique

Fe-N

Ferromagnetic thin films

Perpendicular magnetic anisotropy

Weak stripe domains

Ion implantation

Fe-N

539.7

Engineering Magnetism in Rare Earth Garnet and Metallic Thin Film Heterostructures

Lee, Aidan Jarreau

January 2020

No description available.

Physics

magnetism

sputtering

spintronics

skyrmions

thin films

anisotropy

perpendicular magnetic anisotropy

magnetic damping

magnetotransport

device fabrication

magnetic data storage

ferrimagnetism

ferromagnetism

garnets

alloys

Finite Element Analysis of Bolted Joints with Extra-Long Slots

Suwal, Maiya Laxmi

23 August 2022

No description available.

Engineering

Extra-long slot

Slots perpendicular to applied load

Slots parallel to applied load

Intra-slot bending

Analytical result

Experimental result

Nanoscale investigation of superconductivity and magnetism using neutrons and muons

Ray, Soumya Jyoti

January 2012

The work presented in this thesis was broadly focussed on the investigation of the magnetic behaviour of different superconducting materials in the form of bulk (singe crystals and pellets) and thin films (nanomagnetic devices like superconducting spin valves etc). Neutrons and muons were extensively used to probe the structural and magnetic behaviour of these systems at the nanoscale along with bulk characterisation techniques like high-sensitive magnetic property measurements, scanning probe microscopy and magneto-transport measurements etc. The nanoscale interplay of Superconductivity and Ferromagnetism was studied in the thin film structures using a combination of Polarised Neutron Reflectivity (PNR) and Low Energy Muon Spin Rotation (LE-µSR) techniques while bulk Muon Spin Rotation (µSR) technique was used for microscopic magnetic investigation in the bulk materials. In the Fe/Pb heterostructure, evidence of the Proximity Effect was observed in the form of an enhancement of the superconducting penetration depth (λs) with an increase in the ferromagnetic layer thickness (dF) in both the bilayered and the trilayered structures. The existence of an Inverted Magnetic Region was also detected at the Ferromagnet-Superconductor (F/S) interface in the normal state possibly originating from the induced spin polarisation within the Pb layer in the presence of the neighbouring Fe layer(s). The spatial size (height and width) of the Inverted Magnetic Region did not change much while cooling the sample below the superconducting transition temperature(Tc)and it also stayed unaffected by an increase in the Fe layer thickness and by a change of the applied magnetic field. In the superconducting spin valve structure containing Permalloy (Py) as ferromagnetic layer and Nb as the superconducting layer, LE-µSR measurements revealed the evidence of the decay of magnetic flux density (as a function of thickness) within the Nb layer symmetrically from the Py/Nb interfaces towards the centre of the Nb layer in the normal state. The thickness dependent magnetisation decay occurred over two characteristic length scales in the normal state that stayed of similar values in the superconducting state also. In the superconducting state, an additional contribution towards the magnetisation was found in the vicinity of the Py/Nb interfaces possibly originating from the spin polarisation of the singlet Cooper pairs in these areas. The nanoscale magnetic investigation on a highly engineered F/S/F structure (where each of the F blocks made of multiple Co/Pd layers with magnetic moments aligned perpendicular to the plane of these layers and neighbouring magnetic blocks separated by Ru layers giving rise to antiferromagnetic alignment) using LE-µSR showed an antisymmetric thickness dependent magnetic flux density profile with two characteristic length scales. In the superconducting state, the magnetic flux density profile got modified within the superconducting Nb₆₇Ti₃₃ layer near the F/S interfaces in a way similar to that of observed in the case of Py/Nb system, most likely because of the spin polarisation of the superconducting electron pairs. The vortex magnetic phase diagram of Bi₂Sr₂Ca₂Cu₃O10-δ was studied using the Muon Spin Rotation (µSR) technique to explore the effects of vortex lattice melting and rearrangements for vortex transitions and crossover as a function of magnetic field and temperatures. At low magnetic fields, the flux vortices undergo a first order melting transition from a vortex lattice to a vortex liquid state with increasing temperature while another transition also occurred with increasing field at fixed temperature to a vortex glass phase at the lowest temperatures. Evidence of a frozen liquid phase was found in the intermediate field region at low temperature in the form of a lagoon in the superconducting vortex state which is in agreement with earlier observations made in BiSCCO-2212. The magnetic behaviour of the unconventional superconductor Sr₂RuO₄ was investigated using µSR to find the evidence of normal state magnetism and the nature of the vortex state. In the normal state, a weak hysteretic magnetic signal was detected over a wide temperature and field range believed to be supporting the evidence of a chiral order parameter. The nature of the vortex lattice structure was obtained in different parts of the magnetic phase diagram and the evidence of magnetic field driven transition in the lattice structure was detected from a Triangular→Square structure while the vortex lattice stayed Triangular over the entire temperature region below Tc at low fields with a disappearance of pinning at higher temperatures.

621.3