Transition from ferromagnetism to superparamagnetism in diluted magnetic Fe(II)-doped ZnSe microspheres

•Room-temperature ferromagnetism was observed in Fe2+-doped ZnSe microspheres.•Transition from ferromagnetism to superparamagnetism was observed in doped samples.•The transition temperature increases with the increase of doping concentration. Iron (Fe) doped ZnSe (ZnSe:Fe) microspheres with differen...

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Published in	Journal of magnetism and magnetic materials Vol. 543; p. 168625
Main Authors	Li, Tingting, Wang, Wenhe, Shi, Quan, Zhang, Jian, Zhao, Lijuan
Format	Journal Article
Language	English
Published	Amsterdam Elsevier B.V 01.02.2022 Elsevier BV
Subjects	Diamagnetism Diluted Doping Emission analysis Fe-doped ZnSe Ferromagnetism Inclusions Inductively coupled plasma Iron Lattice parameters Magnetic Magnetic properties Microsphere Microspheres Raman spectra Red shift Room temperature Spin glasses Transition temperature X ray photoelectron spectroscopy Zinc selenide Diluted Microsphere Magnetic Fe-doped ZnSe
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Abstract	•Room-temperature ferromagnetism was observed in Fe2+-doped ZnSe microspheres.•Transition from ferromagnetism to superparamagnetism was observed in doped samples.•The transition temperature increases with the increase of doping concentration. Iron (Fe) doped ZnSe (ZnSe:Fe) microspheres with different doping concentration were prepared by simple solvothermal process. XRD, Raman scattering and SEM results indicated that doping of Fe ions does not change the structure and morphology of ZnSe host. The increase of a-axis lattice parameters and redshift of Raman peaks confirmed the successful incorporation of Fe ions, and XPS results showed that the doped iron is in Fe2+ state. ICP-AES results revealed that the real concentration of Fe incorporated into ZnSe lattice was much lower than the original doping concentration, which is possibly subject to the low solubility of Fe ions in ZnSe host lattice. Optical characterizations showed that increasing Fe concentration would lead to more defects in the host lattice. The magnetic characterizations of ZnSe:Fe microspheres reveal transition from ferromagnetism to superparamagnetism. The transition temperature increases as the increase of doping concentration. Further, these microspheres show a weak room-temperature ferromagnetic exchange interaction was observed by field-dependent magnetization. No evidence of diamagnetism or spin glass state was found in Fe-doped ZnSe microspheres. Due to the lower doping concentration, the dopants could not be expected to cluster or to form inclusions, therefore the observed magnetic behavior is believed to be arising from the random substitution of Fe ions and their magnetic exchange interaction with the delocalized carriers in the ZnSe host.
AbstractList	Iron (Fe) doped ZnSe (ZnSe:Fe) microspheres with different doping concentration were prepared by simple solvothermal process. XRD, Raman scattering and SEM results indicated that doping of Fe ions does not change the structure and morphology of ZnSe host. The increase of a-axis lattice parameters and redshift of Raman peaks confirmed the successful incorporation of Fe ions, and XPS results showed that the doped iron is in Fe2+ state. ICP-AES results revealed that the real concentration of Fe incorporated into ZnSe lattice was much lower than the original doping concentration, which is possibly subject to the low solubility of Fe ions in ZnSe host lattice. Optical characterizations showed that increasing Fe concentration would lead to more defects in the host lattice. The magnetic characterizations of ZnSe:Fe microspheres reveal transition from ferromagnetism to superparamagnetism. The transition temperature increases as the increase of doping concentration. Further, these microspheres show a weak room-temperature ferromagnetic exchange interaction was observed by field-dependent magnetization. No evidence of diamagnetism or spin glass state was found in Fe-doped ZnSe microspheres. Due to the lower doping concentration, the dopants could not be expected to cluster or to form inclusions, therefore the observed magnetic behavior is believed to be arising from the random substitution of Fe ions and their magnetic exchange interaction with the delocalized carriers in the ZnSe host. •Room-temperature ferromagnetism was observed in Fe2+-doped ZnSe microspheres.•Transition from ferromagnetism to superparamagnetism was observed in doped samples.•The transition temperature increases with the increase of doping concentration. Iron (Fe) doped ZnSe (ZnSe:Fe) microspheres with different doping concentration were prepared by simple solvothermal process. XRD, Raman scattering and SEM results indicated that doping of Fe ions does not change the structure and morphology of ZnSe host. The increase of a-axis lattice parameters and redshift of Raman peaks confirmed the successful incorporation of Fe ions, and XPS results showed that the doped iron is in Fe2+ state. ICP-AES results revealed that the real concentration of Fe incorporated into ZnSe lattice was much lower than the original doping concentration, which is possibly subject to the low solubility of Fe ions in ZnSe host lattice. Optical characterizations showed that increasing Fe concentration would lead to more defects in the host lattice. The magnetic characterizations of ZnSe:Fe microspheres reveal transition from ferromagnetism to superparamagnetism. The transition temperature increases as the increase of doping concentration. Further, these microspheres show a weak room-temperature ferromagnetic exchange interaction was observed by field-dependent magnetization. No evidence of diamagnetism or spin glass state was found in Fe-doped ZnSe microspheres. Due to the lower doping concentration, the dopants could not be expected to cluster or to form inclusions, therefore the observed magnetic behavior is believed to be arising from the random substitution of Fe ions and their magnetic exchange interaction with the delocalized carriers in the ZnSe host.
ArticleNumber	168625
Author	Li, Tingting Wang, Wenhe Zhao, Lijuan Zhang, Jian Shi, Quan
Author_xml	– sequence: 1 givenname: Tingting surname: Li fullname: Li, Tingting organization: Materials Genome Institute, Shanghai University, Shanghai 200444, PR China – sequence: 2 givenname: Wenhe surname: Wang fullname: Wang, Wenhe organization: Materials Genome Institute, Shanghai University, Shanghai 200444, PR China – sequence: 3 givenname: Quan surname: Shi fullname: Shi, Quan organization: Materials Genome Institute, Shanghai University, Shanghai 200444, PR China – sequence: 4 givenname: Jian surname: Zhang fullname: Zhang, Jian organization: Shanghai Institute of Ceramics, Chinese Academy of Sciences, Shanghai 200050, PR China – sequence: 5 givenname: Lijuan surname: Zhao fullname: Zhao, Lijuan email: zhaolijuan@t.shu.edu.cn organization: Materials Genome Institute, Shanghai University, Shanghai 200444, PR China
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Snippet	•Room-temperature ferromagnetism was observed in Fe2+-doped ZnSe microspheres.•Transition from ferromagnetism to superparamagnetism was observed in doped... Iron (Fe) doped ZnSe (ZnSe:Fe) microspheres with different doping concentration were prepared by simple solvothermal process. XRD, Raman scattering and SEM...
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SubjectTerms	Diamagnetism Diluted Doping Emission analysis Fe-doped ZnSe Ferromagnetism Inclusions Inductively coupled plasma Iron Lattice parameters Magnetic Magnetic properties Microsphere Microspheres Raman spectra Red shift Room temperature Spin glasses Transition temperature X ray photoelectron spectroscopy Zinc selenide
Title	Transition from ferromagnetism to superparamagnetism in diluted magnetic Fe(II)-doped ZnSe microspheres
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