Role of Si on structure and soft magnetic properties of Fe87−xSixB9Nb3Cu1 ribbons

•Complete amorphous phase is obtained in as spun ribbons upto 25at.% Si alloy.•18% Si alloy exhibits highest glass forming ability as it is at eutectic point.•Annealing of all ribbons yields the precipitation of Nanocrystalline Fe3Si phase.•Si in Fe3Si phase increases from 21 to 25at.% for 11 to 25a...

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Published in	Journal of alloys and compounds Vol. 583; pp. 427 - 433
Main Authors	Srinivas, M., Majumdar, B., Bysakh, S., Manivel Raja, M., Akhtar, D.
Format	Journal Article
Language	English
Published	Kidlington Elsevier B.V 15.01.2014 Elsevier
Subjects	Alloys Amorphous & nanocrystalline Annealing Condensed matter: electronic structure, electrical, magnetic, and optical properties Condensed matter: structure, mechanical and thermal properties Electrical steels Equations of state, phase equilibria, and phase transitions Exact sciences and technology Finemet Glass transitions Intermetallic compounds Iron Magnetic properties Magnetic resonances and relaxations in condensed matter, mössbauer effect Melt spinning Mössbauer effect; other γ-ray spectroscopy Nanocrystals Physics Rapid solidification Ribbons Silicon Silicon steels Specific phase transitions Melt spinning Amorphous & nanocrystalline Finemet Rapid solidification Moessbauer effect Annealing Amorphization Crystallization Paramagnetism Amorphous alloy Soft magnetic materials Glass formation Chemical composition Nanocrystal Iron base alloys
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Abstract	•Complete amorphous phase is obtained in as spun ribbons upto 25at.% Si alloy.•18% Si alloy exhibits highest glass forming ability as it is at eutectic point.•Annealing of all ribbons yields the precipitation of Nanocrystalline Fe3Si phase.•Si in Fe3Si phase increases from 21 to 25at.% for 11 to 25at.% Si alloys.•Coercivity decreases with Si content upto 18% Si and then increases further. Role of Si content on the structural, thermal and soft magnetic properties of melt spun and annealed Fe87−xSixB9Nb3Cu1 (x=11,13,18,20,25 and 30at.%) alloys has been investigated. Processing of ribbons at a higher wheel speed (47m/s) during melt spinning results in the formation of amorphous phase in all the alloys expect for 30at.% Si whereas at lower wheel speed (34m/s), amorphous phase has been observed only in 18at.% Si alloy ribbon. Detailed thermal analyses revealed that higher glass forming ability of 18at.% Si alloy is due to the near eutectic point in these alloy series and higher ratio between the crystallization and liquidus temperature (Tx/TL). On annealing, nanocrystalline Fe3Si phase was found to be precipitated out in amorphous matrix in alloys up to 20at.% Si ribbons whereas paramagnetic Fe4.9Si2B phase along with Fe3Si phase was observed in 25% Si ribbon. Detailed Mössbauer spectroscopy of the annealed ribbons revealed that the composition of the nanocrystalline Fe3Si phase increases from Fe-21at.% Si towards the stoichiometric composition (Fe-25at.% Si) with Si content. The results are also corroborated with precision lattice parameter measurements. The coercivity of the annealed ribbons initially decreases, attains a minimum at 18at.% Si and then increases abruptly with Si content.
AbstractList	Role of Si content on the structural, thermal and soft magnetic properties of melt spun and annealed Fe87-xSixB9Nb3Cu1 (x = 11, 13, 18, 20, 25 and 30 at.%) alloys has been investigated. Processing of ribbons at a higher wheel speed (47 m/s) during melt spinning results in the formation of amorphous phase in all the alloys expect for 30 at.% Si whereas at lower wheel speed (34 m/s), amorphous phase has been observed only in 18 at.% Si alloy ribbon. Detailed thermal analyses revealed that higher glass forming ability of 18 at.% Si alloy is due to the near eutectic point in these alloy series and higher ratio between the crystallization and liquidus temperature (Tx/TL). On annealing, nanocrystalline Fe3Si phase was found to be precipitated out in amorphous matrix in alloys up to 20 at.% Si ribbons whereas paramagnetic Fe4.9Si2B phase along with Fe3Si phase was observed in 25% Si ribbon. Detailed Mossbauer spectroscopy of the annealed ribbons revealed that the composition of the nanocrystalline Fe3Si phase increases from Fe-21 at.% Si towards the stoichiometric composition (Fe-25 at.% Si) with Si content. The results are also corroborated with precision lattice parameter measurements. The coercivity of the annealed ribbons initially decreases, attains a minimum at 18 at.% Si and then increases abruptly with Si content. •Complete amorphous phase is obtained in as spun ribbons upto 25at.% Si alloy.•18% Si alloy exhibits highest glass forming ability as it is at eutectic point.•Annealing of all ribbons yields the precipitation of Nanocrystalline Fe3Si phase.•Si in Fe3Si phase increases from 21 to 25at.% for 11 to 25at.% Si alloys.•Coercivity decreases with Si content upto 18% Si and then increases further. Role of Si content on the structural, thermal and soft magnetic properties of melt spun and annealed Fe87−xSixB9Nb3Cu1 (x=11,13,18,20,25 and 30at.%) alloys has been investigated. Processing of ribbons at a higher wheel speed (47m/s) during melt spinning results in the formation of amorphous phase in all the alloys expect for 30at.% Si whereas at lower wheel speed (34m/s), amorphous phase has been observed only in 18at.% Si alloy ribbon. Detailed thermal analyses revealed that higher glass forming ability of 18at.% Si alloy is due to the near eutectic point in these alloy series and higher ratio between the crystallization and liquidus temperature (Tx/TL). On annealing, nanocrystalline Fe3Si phase was found to be precipitated out in amorphous matrix in alloys up to 20at.% Si ribbons whereas paramagnetic Fe4.9Si2B phase along with Fe3Si phase was observed in 25% Si ribbon. Detailed Mössbauer spectroscopy of the annealed ribbons revealed that the composition of the nanocrystalline Fe3Si phase increases from Fe-21at.% Si towards the stoichiometric composition (Fe-25at.% Si) with Si content. The results are also corroborated with precision lattice parameter measurements. The coercivity of the annealed ribbons initially decreases, attains a minimum at 18at.% Si and then increases abruptly with Si content.
Author	Manivel Raja, M. Majumdar, B. Srinivas, M. Akhtar, D. Bysakh, S.
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Snippet	•Complete amorphous phase is obtained in as spun ribbons upto 25at.% Si alloy.•18% Si alloy exhibits highest glass forming ability as it is at eutectic... Role of Si content on the structural, thermal and soft magnetic properties of melt spun and annealed Fe87-xSixB9Nb3Cu1 (x = 11, 13, 18, 20, 25 and 30 at.%)...
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SubjectTerms	Alloys Amorphous & nanocrystalline Annealing Condensed matter: electronic structure, electrical, magnetic, and optical properties Condensed matter: structure, mechanical and thermal properties Electrical steels Equations of state, phase equilibria, and phase transitions Exact sciences and technology Finemet Glass transitions Intermetallic compounds Iron Magnetic properties Magnetic resonances and relaxations in condensed matter, mössbauer effect Melt spinning Mössbauer effect; other γ-ray spectroscopy Nanocrystals Physics Rapid solidification Ribbons Silicon Silicon steels Specific phase transitions
Title	Role of Si on structure and soft magnetic properties of Fe87−xSixB9Nb3Cu1 ribbons
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