Spin excitations in 3D molecular magnets probed by neutron scattering

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Spin excitations in 3D molecular magnets probed by neutron scattering. / Bordallo, H. N.; Chapon, L. C.; Cook, J. C.; Copley, J. R.D.; Goremychkin, E.; Kern, S.; Lee, S. H.; Yildirim, T.; Manson, J. L.

In: Applied Physics A: Materials Science and Processing, Vol. 74, No. SUPPL.I, 01.12.2002.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Bordallo, HN, Chapon, LC, Cook, JC, Copley, JRD, Goremychkin, E, Kern, S, Lee, SH, Yildirim, T & Manson, JL 2002, 'Spin excitations in 3D molecular magnets probed by neutron scattering', Applied Physics A: Materials Science and Processing, vol. 74, no. SUPPL.I. https://doi.org/10.1007/s003390201350

APA

Bordallo, H. N., Chapon, L. C., Cook, J. C., Copley, J. R. D., Goremychkin, E., Kern, S., Lee, S. H., Yildirim, T., & Manson, J. L. (2002). Spin excitations in 3D molecular magnets probed by neutron scattering. Applied Physics A: Materials Science and Processing, 74(SUPPL.I). https://doi.org/10.1007/s003390201350

Vancouver

Bordallo HN, Chapon LC, Cook JC, Copley JRD, Goremychkin E, Kern S et al. Spin excitations in 3D molecular magnets probed by neutron scattering. Applied Physics A: Materials Science and Processing. 2002 Dec 1;74(SUPPL.I). https://doi.org/10.1007/s003390201350

Author

Bordallo, H. N. ; Chapon, L. C. ; Cook, J. C. ; Copley, J. R.D. ; Goremychkin, E. ; Kern, S. ; Lee, S. H. ; Yildirim, T. ; Manson, J. L. / Spin excitations in 3D molecular magnets probed by neutron scattering. In: Applied Physics A: Materials Science and Processing. 2002 ; Vol. 74, No. SUPPL.I.

Bibtex

@article{f078cb188c3f4838a0e2efc7870f01ab,
title = "Spin excitations in 3D molecular magnets probed by neutron scattering",
abstract = "The emerging field of molecular magnetism constitutes a new branch of materials science that deals with the magnetic properties of molecules, or assemblies of molecules, that contain magnetic centers. The growing interest in understanding the origin of the magnetic ordering in these materials is to obtain novel multiproperty molecular magnetic materials with high transition temperatures. Molecules based on the dicyanamide ion [NΞC-N-CΞN], abbreviated (dca), such as M(dca)2 [M = Mn, Ni], have shown interesting bulk properties that prompted our inelastic neutron scattering (INS) studies. While the Mn2+ ion is isotropic because of its L = 0 configuration, the isostructural Ni analog has S = 1 and demonstrates marked single-ion anisotropy. Mn(dca)2 is a canted antiferromagnet below 16 K, while Ni(dca)2 is a ferromagnet below 21 K. INS has been used to investigate the magnetic excitations in Mn(dca)2 and Ni(dca)2. For Mn(dca)2, a Heisenberg model gives good correspondence with the experimental results.",
author = "Bordallo, {H. N.} and Chapon, {L. C.} and Cook, {J. C.} and Copley, {J. R.D.} and E. Goremychkin and S. Kern and Lee, {S. H.} and T. Yildirim and Manson, {J. L.}",
year = "2002",
month = dec,
day = "1",
doi = "10.1007/s003390201350",
language = "English",
volume = "74",
journal = "Applied Physics A: Materials Science & Processing",
issn = "0947-8396",
publisher = "Springer",
number = "SUPPL.I",

}

RIS

TY - JOUR

T1 - Spin excitations in 3D molecular magnets probed by neutron scattering

AU - Bordallo, H. N.

AU - Chapon, L. C.

AU - Cook, J. C.

AU - Copley, J. R.D.

AU - Goremychkin, E.

AU - Kern, S.

AU - Lee, S. H.

AU - Yildirim, T.

AU - Manson, J. L.

PY - 2002/12/1

Y1 - 2002/12/1

N2 - The emerging field of molecular magnetism constitutes a new branch of materials science that deals with the magnetic properties of molecules, or assemblies of molecules, that contain magnetic centers. The growing interest in understanding the origin of the magnetic ordering in these materials is to obtain novel multiproperty molecular magnetic materials with high transition temperatures. Molecules based on the dicyanamide ion [NΞC-N-CΞN], abbreviated (dca), such as M(dca)2 [M = Mn, Ni], have shown interesting bulk properties that prompted our inelastic neutron scattering (INS) studies. While the Mn2+ ion is isotropic because of its L = 0 configuration, the isostructural Ni analog has S = 1 and demonstrates marked single-ion anisotropy. Mn(dca)2 is a canted antiferromagnet below 16 K, while Ni(dca)2 is a ferromagnet below 21 K. INS has been used to investigate the magnetic excitations in Mn(dca)2 and Ni(dca)2. For Mn(dca)2, a Heisenberg model gives good correspondence with the experimental results.

AB - The emerging field of molecular magnetism constitutes a new branch of materials science that deals with the magnetic properties of molecules, or assemblies of molecules, that contain magnetic centers. The growing interest in understanding the origin of the magnetic ordering in these materials is to obtain novel multiproperty molecular magnetic materials with high transition temperatures. Molecules based on the dicyanamide ion [NΞC-N-CΞN], abbreviated (dca), such as M(dca)2 [M = Mn, Ni], have shown interesting bulk properties that prompted our inelastic neutron scattering (INS) studies. While the Mn2+ ion is isotropic because of its L = 0 configuration, the isostructural Ni analog has S = 1 and demonstrates marked single-ion anisotropy. Mn(dca)2 is a canted antiferromagnet below 16 K, while Ni(dca)2 is a ferromagnet below 21 K. INS has been used to investigate the magnetic excitations in Mn(dca)2 and Ni(dca)2. For Mn(dca)2, a Heisenberg model gives good correspondence with the experimental results.

UR - http://www.scopus.com/inward/record.url?scp=0347297383&partnerID=8YFLogxK

U2 - 10.1007/s003390201350

DO - 10.1007/s003390201350

M3 - Journal article

AN - SCOPUS:0347297383

VL - 74

JO - Applied Physics A: Materials Science & Processing

JF - Applied Physics A: Materials Science & Processing

SN - 0947-8396

IS - SUPPL.I

ER -

ID: 203940565