Effect of FePd alloy composition on the dynamics of artificial spin ice

Artificial spin ices (ASI) are arrays of single domain nano-magnetic islands, arranged in geometries that give rise to frustrated magnetostatic interactions. It is possible to reach their ground state via thermal annealing. We have made square ASI using different FePd alloys to vary the magnetizatio...

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Veröffentlicht in:	arXiv.org 2017-12
Hauptverfasser:	Morley, Sophie A, Riley, Susan T, Jose-Maria Porro, Rosamond, Mark C, Linfield, Edmund H, Cunningham, John E, Langridge, Sean, Marrows, Christopher H
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Sprache:	eng
Schlagworte:	Apexes Collapse Composition effects Ferrous alloys Ground state Intermetallic compounds Iron compounds Magnetic fields Magnetic islands Magnetization Palladium compounds Physics - Materials Science Physics - Mesoscale and Nanoscale Physics Spin dynamics Spin ice Sputtering Temperature
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description	Artificial spin ices (ASI) are arrays of single domain nano-magnetic islands, arranged in geometries that give rise to frustrated magnetostatic interactions. It is possible to reach their ground state via thermal annealing. We have made square ASI using different FePd alloys to vary the magnetization via co-sputtering. From a polarized state the samples were incrementally heated and we measured the vertex population as a function of temperature using magnetic force microscopy. For the higher magnetization FePd sample, we report an onset of dynamics at $T = 493$ K, with a rapid collapse into $>90\%$ ground state vertices. In contrast, the low magnetization sample started to fluctuate at lower temperatures, $T = 393$ K and over a wider temperature range but only reached a maximum of $25\%$ of ground state vertices. These results indicate that the interaction strength, dynamic temperature range and pathways can be finely tuned using a simple co-sputtering process. In addition we have compared our experimental values of the blocking temperature to those predicted using the simple N\'{e}el-Brown two-state model and find a large discrepancy which we attribute to activation volumes much smaller than the island volume.
doi_str_mv	10.48550/arxiv.1712.02404
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It is possible to reach their ground state via thermal annealing. We have made square ASI using different FePd alloys to vary the magnetization via co-sputtering. From a polarized state the samples were incrementally heated and we measured the vertex population as a function of temperature using magnetic force microscopy. For the higher magnetization FePd sample, we report an onset of dynamics at $T = 493$ K, with a rapid collapse into $>90\%$ ground state vertices. In contrast, the low magnetization sample started to fluctuate at lower temperatures, $T = 393$ K and over a wider temperature range but only reached a maximum of $25\%$ of ground state vertices. These results indicate that the interaction strength, dynamic temperature range and pathways can be finely tuned using a simple co-sputtering process. 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subjects	Apexes Collapse Composition effects Ferrous alloys Ground state Intermetallic compounds Iron compounds Magnetic fields Magnetic islands Magnetization Palladium compounds Physics - Materials Science Physics - Mesoscale and Nanoscale Physics Spin dynamics Spin ice Sputtering Temperature
title	Effect of FePd alloy composition on the dynamics of artificial spin ice
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