Giant magnetoresistance and structure of electrodeposited Co/Cu multilayers: the influence of layer thicknesses and Cu deposition potential
N. Rajasekaran, J. Mani, B.G. T\'oth, G. Moln\'ar, S. Mohan, L., P\'eter, I. Bakonyi

TL;DR
This study investigates how layer thicknesses and Cu deposition potential affect the giant magnetoresistance and structure of electrodeposited Co/Cu multilayers, revealing the dominance of ferromagnetic contributions and the impact of surface roughness.
Contribution
It provides new insights into the relationship between deposition parameters, multilayer structure, and GMR behavior in electrodeposited Co/Cu multilayers.
Findings
GMR dominated by ferromagnetic contribution even without visible superlattice satellites.
GMR increases with multilayer thickness due to surface roughness and SPM contribution.
Improved structural quality correlates with reduced surface roughness and altered GMR components.
Abstract
The giant magnetoresistance (GMR) and structure was investigated for electrodeposited Co/Cu multilayers prepared by a conventional galvanostatic/potentiostatic pulse combination from a pure sulfate electrolyte with various layer thicknesses, total multilayer thickness and Cu deposition potential. X-ray diffraction (XRD) measurements revealed superlattice satellite reflections for many of the multilayers having sufficiently large thickness (at least 2 nm) of both constituent layers. The bilayer repeats derived from the positions of the visible superlattice reflections were typically 10-20% higher than the nominal values.The observed GMR was found to be dominated by the multilayer-like ferromagnetic (FM) contribution even for multilayers without visible superlattice satellites. There was always also a modest superparamagnetic (SPM) contribution to the GMR and this term was the largest for…
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