Spin dynamics and spin freezing at ferromagnetic quantum phase transitions

P. Schmakat; M. Wagner; R. Ritz; A. Bauer; M. Brando; M. Deppe; W. Duncan; C. Duvinage; C. Franz; C. Geibel; F. M. Grosche; M. Hirschberger; K. Hradil; M. Meven; A. Neubauer; M. Schulz; A. Senyshyn; S. Süllow; B. Pedersen; P. Böni; C. Pfleiderer

doi:10.1140/epjst/e2015-02445-4

Spin dynamics and spin freezing at ferromagnetic quantum phase transitions

P. Schmakat, M. Wagner, R. Ritz, A. Bauer, M. Brando, M. Deppe, W. Duncan, C. Duvinage, C. Franz, C. Geibel, F. M. Grosche, M. Hirschberger, K. Hradil, M. Meven, A. Neubauer, M. Schulz, A. Senyshyn, S. Süllow, B. Pedersen, P. BöniC. Pfleiderer

Research output: Contribution to journal › Review article › peer-review

10 Scopus citations

Abstract

We report selected experimental results on the spin dynamics and spin freezing at ferromagnetic quantum phase transitions to illustrate some of the most prominent escape routes by which ferromagnetic quantum criticality is avoided in real materials. In the transition metal Heusler compound Fe₂TiSn we observe evidence for incipient ferromagnetic quantum criticality. High pressure studies in MnSi reveal empirical evidence for a topological non-Fermi liquid state without quantum criticality. Single crystals of the hexagonal Laves phase compound Nb_1−yFe_2+y provide evidence of a ferromagnetic to spin density wave transition as a function of slight compositional changes. Last but not least, neutron depolarisation imaging in CePd₁−_xRh_x underscore evidence taken from the bulk properties of the formation of a Kondo cluster glass.

Original language	English
Article number	A005
Pages (from-to)	1041-1060
Number of pages	20
Journal	European Physical Journal: Special Topics
Volume	224
Issue number	6
DOIs	https://doi.org/10.1140/epjst/e2015-02445-4
State	Published - 1 Jul 2015

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Schmakat, P., Wagner, M., Ritz, R., Bauer, A., Brando, M., Deppe, M., Duncan, W., Duvinage, C., Franz, C., Geibel, C., Grosche, F. M., Hirschberger, M., Hradil, K., Meven, M., Neubauer, A., Schulz, M., Senyshyn, A., Süllow, S., Pedersen, B., ... Pfleiderer, C. (2015). Spin dynamics and spin freezing at ferromagnetic quantum phase transitions. European Physical Journal: Special Topics, 224(6), 1041-1060. Article A005. https://doi.org/10.1140/epjst/e2015-02445-4

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title = "Spin dynamics and spin freezing at ferromagnetic quantum phase transitions",

abstract = "We report selected experimental results on the spin dynamics and spin freezing at ferromagnetic quantum phase transitions to illustrate some of the most prominent escape routes by which ferromagnetic quantum criticality is avoided in real materials. In the transition metal Heusler compound Fe2TiSn we observe evidence for incipient ferromagnetic quantum criticality. High pressure studies in MnSi reveal empirical evidence for a topological non-Fermi liquid state without quantum criticality. Single crystals of the hexagonal Laves phase compound Nb1−yFe2+y provide evidence of a ferromagnetic to spin density wave transition as a function of slight compositional changes. Last but not least, neutron depolarisation imaging in CePd1−xRhx underscore evidence taken from the bulk properties of the formation of a Kondo cluster glass.",

author = "P. Schmakat and M. Wagner and R. Ritz and A. Bauer and M. Brando and M. Deppe and W. Duncan and C. Duvinage and C. Franz and C. Geibel and Grosche, {F. M.} and M. Hirschberger and K. Hradil and M. Meven and A. Neubauer and M. Schulz and A. Senyshyn and S. S{\"u}llow and B. Pedersen and P. B{\"o}ni and C. Pfleiderer",

note = "Publisher Copyright: {\textcopyright} EDP Sciences, Springer-Verlag 2015.",

year = "2015",

month = jul,

day = "1",

doi = "10.1140/epjst/e2015-02445-4",

language = "English",

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Schmakat, P, Wagner, M, Ritz, R, Bauer, A, Brando, M, Deppe, M, Duncan, W, Duvinage, C, Franz, C, Geibel, C, Grosche, FM, Hirschberger, M, Hradil, K, Meven, M, Neubauer, A, Schulz, M, Senyshyn, A, Süllow, S, Pedersen, B, Böni, P & Pfleiderer, C 2015, 'Spin dynamics and spin freezing at ferromagnetic quantum phase transitions', European Physical Journal: Special Topics, vol. 224, no. 6, A005, pp. 1041-1060. https://doi.org/10.1140/epjst/e2015-02445-4

TY - JOUR

T1 - Spin dynamics and spin freezing at ferromagnetic quantum phase transitions

AU - Schmakat, P.

AU - Wagner, M.

AU - Ritz, R.

AU - Bauer, A.

AU - Brando, M.

AU - Deppe, M.

AU - Duncan, W.

AU - Duvinage, C.

AU - Franz, C.

AU - Geibel, C.

AU - Grosche, F. M.

AU - Hirschberger, M.

AU - Hradil, K.

AU - Meven, M.

AU - Neubauer, A.

AU - Schulz, M.

AU - Senyshyn, A.

AU - Süllow, S.

AU - Pedersen, B.

AU - Böni, P.

AU - Pfleiderer, C.

PY - 2015/7/1

Y1 - 2015/7/1

N2 - We report selected experimental results on the spin dynamics and spin freezing at ferromagnetic quantum phase transitions to illustrate some of the most prominent escape routes by which ferromagnetic quantum criticality is avoided in real materials. In the transition metal Heusler compound Fe2TiSn we observe evidence for incipient ferromagnetic quantum criticality. High pressure studies in MnSi reveal empirical evidence for a topological non-Fermi liquid state without quantum criticality. Single crystals of the hexagonal Laves phase compound Nb1−yFe2+y provide evidence of a ferromagnetic to spin density wave transition as a function of slight compositional changes. Last but not least, neutron depolarisation imaging in CePd1−xRhx underscore evidence taken from the bulk properties of the formation of a Kondo cluster glass.

AB - We report selected experimental results on the spin dynamics and spin freezing at ferromagnetic quantum phase transitions to illustrate some of the most prominent escape routes by which ferromagnetic quantum criticality is avoided in real materials. In the transition metal Heusler compound Fe2TiSn we observe evidence for incipient ferromagnetic quantum criticality. High pressure studies in MnSi reveal empirical evidence for a topological non-Fermi liquid state without quantum criticality. Single crystals of the hexagonal Laves phase compound Nb1−yFe2+y provide evidence of a ferromagnetic to spin density wave transition as a function of slight compositional changes. Last but not least, neutron depolarisation imaging in CePd1−xRhx underscore evidence taken from the bulk properties of the formation of a Kondo cluster glass.

UR - http://www.scopus.com/inward/record.url?scp=84943275422&partnerID=8YFLogxK

U2 - 10.1140/epjst/e2015-02445-4

DO - 10.1140/epjst/e2015-02445-4

M3 - Review article

AN - SCOPUS:84943275422

SN - 1951-6355

VL - 224

SP - 1041

EP - 1060

JO - European Physical Journal: Special Topics

JF - European Physical Journal: Special Topics

IS - 6

M1 - A005

ER -

Spin dynamics and spin freezing at ferromagnetic quantum phase transitions

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