Magnetic properties of ordered polycrystalline FeRh thin films

Jingfan Ye; Marco Hauke; Vikram Singh; Rajeev Rawat; Mukul Gupta; Akhil Tayal; S. M. Amir; Jochen Stahn; Amitesh Paul

doi:10.1039/c7ra06738k

Magnetic properties of ordered polycrystalline FeRh thin films

Jingfan Ye, Marco Hauke, Vikram Singh, Rajeev Rawat, Mukul Gupta, Akhil Tayal, S. M. Amir, Jochen Stahn, Amitesh Paul^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

FeRh alloys with B2-order have been investigated earlier in epitaxial films as the metamagnetic transition temperature (T_AF-FM) depends upon the structure and lattice strain or disorder. Here, we report on an ordered polycrystalline FeRh film on Al₂O₃ (0001) deposited by DC magnetron sputtering. We found that T_AF-FM = 346 K (in 1 T), which can be shifted by a magnetic field to 288 K (in 7 T) with similar rates (dT/dH) of -8.5 K T^-1 (heating) and -9.6 K T^-1 (cooling) as in epitaxial ones. However, a significant difference in the rate of domain nucleation and propagation with temperature (dM/dT) during cooling and heating procedures is noted. These changes can be ascribed to ordered and disordered polycrystallinity of the film. Furthermore, polarized neutron reflectometry (PNR) shows that the FeRh film is not homogeneous throughout the depth of the film. On the one hand, we found evidence of Fe segregation at the surface of the film extended to within a few nanometers from the top-interface and on the other hand, Rh richness at the substrate-interface. A gradient in Fe at% has resulted in changing magnetic phases from ordered bcc (B2) within the film to a disordered bcc (A2) structure at the surface and a disordered fcc phase (A1) at the bottom. Thus it is possible to grow commercially viable polycrystalline films with similar characteristics to those of epitaxial films.

Original language	English
Pages (from-to)	44097-44103
Number of pages	7
Journal	RSC Advances
Volume	7
Issue number	70
DOIs	https://doi.org/10.1039/c7ra06738k
State	Published - 2017
Externally published	Yes

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title = "Magnetic properties of ordered polycrystalline FeRh thin films",

abstract = "FeRh alloys with B2-order have been investigated earlier in epitaxial films as the metamagnetic transition temperature (TAF-FM) depends upon the structure and lattice strain or disorder. Here, we report on an ordered polycrystalline FeRh film on Al2O3 (0001) deposited by DC magnetron sputtering. We found that TAF-FM = 346 K (in 1 T), which can be shifted by a magnetic field to 288 K (in 7 T) with similar rates (dT/dH) of -8.5 K T-1 (heating) and -9.6 K T-1 (cooling) as in epitaxial ones. However, a significant difference in the rate of domain nucleation and propagation with temperature (dM/dT) during cooling and heating procedures is noted. These changes can be ascribed to ordered and disordered polycrystallinity of the film. Furthermore, polarized neutron reflectometry (PNR) shows that the FeRh film is not homogeneous throughout the depth of the film. On the one hand, we found evidence of Fe segregation at the surface of the film extended to within a few nanometers from the top-interface and on the other hand, Rh richness at the substrate-interface. A gradient in Fe at% has resulted in changing magnetic phases from ordered bcc (B2) within the film to a disordered bcc (A2) structure at the surface and a disordered fcc phase (A1) at the bottom. Thus it is possible to grow commercially viable polycrystalline films with similar characteristics to those of epitaxial films.",

author = "Jingfan Ye and Marco Hauke and Vikram Singh and Rajeev Rawat and Mukul Gupta and Akhil Tayal and Amir, {S. M.} and Jochen Stahn and Amitesh Paul",

note = "Publisher Copyright: {\textcopyright} 2017 The Royal Society of Chemistry.",

year = "2017",

doi = "10.1039/c7ra06738k",

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T1 - Magnetic properties of ordered polycrystalline FeRh thin films

AU - Ye, Jingfan

AU - Hauke, Marco

AU - Singh, Vikram

AU - Rawat, Rajeev

AU - Gupta, Mukul

AU - Tayal, Akhil

AU - Amir, S. M.

AU - Stahn, Jochen

AU - Paul, Amitesh

PY - 2017

Y1 - 2017

N2 - FeRh alloys with B2-order have been investigated earlier in epitaxial films as the metamagnetic transition temperature (TAF-FM) depends upon the structure and lattice strain or disorder. Here, we report on an ordered polycrystalline FeRh film on Al2O3 (0001) deposited by DC magnetron sputtering. We found that TAF-FM = 346 K (in 1 T), which can be shifted by a magnetic field to 288 K (in 7 T) with similar rates (dT/dH) of -8.5 K T-1 (heating) and -9.6 K T-1 (cooling) as in epitaxial ones. However, a significant difference in the rate of domain nucleation and propagation with temperature (dM/dT) during cooling and heating procedures is noted. These changes can be ascribed to ordered and disordered polycrystallinity of the film. Furthermore, polarized neutron reflectometry (PNR) shows that the FeRh film is not homogeneous throughout the depth of the film. On the one hand, we found evidence of Fe segregation at the surface of the film extended to within a few nanometers from the top-interface and on the other hand, Rh richness at the substrate-interface. A gradient in Fe at% has resulted in changing magnetic phases from ordered bcc (B2) within the film to a disordered bcc (A2) structure at the surface and a disordered fcc phase (A1) at the bottom. Thus it is possible to grow commercially viable polycrystalline films with similar characteristics to those of epitaxial films.

AB - FeRh alloys with B2-order have been investigated earlier in epitaxial films as the metamagnetic transition temperature (TAF-FM) depends upon the structure and lattice strain or disorder. Here, we report on an ordered polycrystalline FeRh film on Al2O3 (0001) deposited by DC magnetron sputtering. We found that TAF-FM = 346 K (in 1 T), which can be shifted by a magnetic field to 288 K (in 7 T) with similar rates (dT/dH) of -8.5 K T-1 (heating) and -9.6 K T-1 (cooling) as in epitaxial ones. However, a significant difference in the rate of domain nucleation and propagation with temperature (dM/dT) during cooling and heating procedures is noted. These changes can be ascribed to ordered and disordered polycrystallinity of the film. Furthermore, polarized neutron reflectometry (PNR) shows that the FeRh film is not homogeneous throughout the depth of the film. On the one hand, we found evidence of Fe segregation at the surface of the film extended to within a few nanometers from the top-interface and on the other hand, Rh richness at the substrate-interface. A gradient in Fe at% has resulted in changing magnetic phases from ordered bcc (B2) within the film to a disordered bcc (A2) structure at the surface and a disordered fcc phase (A1) at the bottom. Thus it is possible to grow commercially viable polycrystalline films with similar characteristics to those of epitaxial films.

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JO - RSC Advances

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ER -

Magnetic properties of ordered polycrystalline FeRh thin films

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