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This thesis reports a successful fabrication and characterisation of ferromagnetic/superconductor junction (F/S) on graphene. The thesis preposes a fabrication method to produce F/S junctions on graphene which make use of ALD grown Al2O3 as the tunnel barrier for the ferromagnetic contacts. Measurements done on F/G/S/G/F suggests that by injecting spin polarised current into the superconductor, a spin imbalance is created in the quasiparticle density of states of the superconductor which then diffuses through the graphene channel. The observed characteristic curves are similar to the ones which are already reported on metallic ferromagnet/superconductor junctions where the spin imbalance is created using Zeeman splitting. Further measurements also show that the curves loose their characteristic shapes when the temperature is increased above the critical temperature (Tc) or when the external magnetic field is higher then the critical field (Hc) of the superconducting contact. But to prove conclusively and doubtlessly the existence of spin imbalance in ferromagnet/superconductor junctions on graphene, more devices have to be made and characterised preferably in a dilution refrigerator.
Fabrication and characterization of CPP-GMR and spin-transfer torque induced magnetic switching
(2014)
Even though the unique magnetic behavior for ferromagnets has been known for thousands of years, explaining this interesting phenomenon only occurred in the 20th century. It was in 1920, with the discovery of electron spin, that a clear explanation of how ferromagnets achieve their unique magnetic properties came to light. The electron carries an intrinsic electric charge and intrinsic angular momentum. Use of this property in a device was achieved in 1998 when Fert and Gru¨nberg independently found that the resistance of FM/NM/FM trilayer depended on the angle between the magnetization of the two layers. This phenomena which is called giant magnetoresistance (GMR) brought spin transfer into mainstream. This new discovery created a brand new research fi called “spintronics” or “spin based electronics” which exploits the intrinsic spin of electron.
As expected spintronics delivered a new generation of magnetic devices which are currently used in magnetic disk drives and magnetic random access memories (MRAM). The potential advantages of spintronics devices are non-volatility, higher speed, increased data density and low power consumption. GMR devices are already used in industry as magnetic memories and read heads.
The quality of GMR devices can be increased by developing new magnetic materials and also by going down to nanoscale. The desired characteristic properties of these new materials are higher spin polarization, higher curie temperature and better spin filtering. Half-metals are a good candidate for these devices since they are expected to have high polarization. Some examples of half-metals are Half-Heusler alloy, full Heusler alloy and Perovskite or double Perovskite oxides. The devices discussed in this thesis have NiMnSb half-Heusler alloy and permalloy as the ferromagnetic layers separated by Cu as the nonmagnetic layer.
This dissertation includes mainly two parts, fabrication and characterization of nan- opillars. The layer stack used for the fabrication is Ru/Py/Cu/NiMnSb which is grown on an InP substrate with an (In,Ga)As buff by molecule beam epitaxy (MBE). A new method of fabrication using metal mask which has a higher yield of working samples over the previous method (using the resist mask) used in our group is discussed in detail. Also, the advantages of this new method and draw backs of the old method are explained thoroughly (in chapter 3).
The second part (chapters 4 and 5) is focused on electrical measurements and charac- terization of the nanopillar, specially with regard to GMR and spin-transfer torque (STT)
measurements. In chapter 4, the results of current perpendicular the plane giant mag- netoresistance (CPP-GMR) measurements at various temperatures and in-plane magnetic fi are presented. The dependence of CPP-GMR on bias current and shape anisotropy of the device are investigated. Results of these measurements show that the device has strong shape anisotropy.
The following chapter deals with spin-transfer torque induced magnetic switching measurements done on the device. Critical current densities are on the order of 106 A/cm2, which is one order of magnitude smaller than the current industry standards. Our results show that the two possible magnetic configurations of the nanopillar (parallel and anti-parallel) have a strong dependence on the applied in-plane magnetic fi Fi- nally, four magnetic fi regimes based on the stability of the magnetic configuration (P stable, AP stable, both P and AP stable, both P and AP unstable) are identified.