Neutron diffraction in a model itinerant metal near a quantum critical point

D. A. Sokolov; M. C. Aronson; R. Erwin; J. W. Lynn; M. D. Lumsden; S. E. Nagler

doi:10.1088/1742-6596/150/4/042189

Neutron diffraction in a model itinerant metal near a quantum critical point

D. A. Sokolov, M. C. Aronson, R. Erwin, J. W. Lynn, M. D. Lumsden, S. E. Nagler

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

Abstract

Neutron diffraction measurements on single crystals of Cr _1-xV_x (x=0, 0.02, 0.037) show that the ordering moment and the Neel temperature are continuously suppressed as x approaches 0.037, a proposed Quantum Critical Point (QCP). The wave vector Q of the spin density wave (SDW) becomes more incommensurate as x increases in accordance with the two band model. At x_C=0.037 we have found temperature dependent, resolution limited elastic scattering at 4 incommensurate wave vectors Q=(1 δ_1,2, 0, 0)*2π/a, which correspond to 2 SDWs with Neel temperatures of 19 K and 300 K. Our neutron diffraction measurements indicate that the electronic structure of Cr is robust, and that tuning Cr to its QCP results not in the suppression of antiferromagnetism, but instead enables new spin ordering due to novel nesting of the Fermi surface of Cr.

Original language	English
Article number	042189
Journal	Journal of Physics: Conference Series
Volume	150
Issue number	4
DOIs	https://doi.org/10.1088/1742-6596/150/4/042189
State	Published - 2009
Externally published	Yes

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title = "Neutron diffraction in a model itinerant metal near a quantum critical point",

abstract = "Neutron diffraction measurements on single crystals of Cr 1-xVx (x=0, 0.02, 0.037) show that the ordering moment and the Neel temperature are continuously suppressed as x approaches 0.037, a proposed Quantum Critical Point (QCP). The wave vector Q of the spin density wave (SDW) becomes more incommensurate as x increases in accordance with the two band model. At xC=0.037 we have found temperature dependent, resolution limited elastic scattering at 4 incommensurate wave vectors Q=(1 δ1,2, 0, 0)*2π/a, which correspond to 2 SDWs with Neel temperatures of 19 K and 300 K. Our neutron diffraction measurements indicate that the electronic structure of Cr is robust, and that tuning Cr to its QCP results not in the suppression of antiferromagnetism, but instead enables new spin ordering due to novel nesting of the Fermi surface of Cr.",

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T1 - Neutron diffraction in a model itinerant metal near a quantum critical point

AU - Sokolov, D. A.

AU - Aronson, M. C.

AU - Erwin, R.

AU - Lynn, J. W.

AU - Lumsden, M. D.

AU - Nagler, S. E.

PY - 2009

Y1 - 2009

N2 - Neutron diffraction measurements on single crystals of Cr 1-xVx (x=0, 0.02, 0.037) show that the ordering moment and the Neel temperature are continuously suppressed as x approaches 0.037, a proposed Quantum Critical Point (QCP). The wave vector Q of the spin density wave (SDW) becomes more incommensurate as x increases in accordance with the two band model. At xC=0.037 we have found temperature dependent, resolution limited elastic scattering at 4 incommensurate wave vectors Q=(1 δ1,2, 0, 0)*2π/a, which correspond to 2 SDWs with Neel temperatures of 19 K and 300 K. Our neutron diffraction measurements indicate that the electronic structure of Cr is robust, and that tuning Cr to its QCP results not in the suppression of antiferromagnetism, but instead enables new spin ordering due to novel nesting of the Fermi surface of Cr.

AB - Neutron diffraction measurements on single crystals of Cr 1-xVx (x=0, 0.02, 0.037) show that the ordering moment and the Neel temperature are continuously suppressed as x approaches 0.037, a proposed Quantum Critical Point (QCP). The wave vector Q of the spin density wave (SDW) becomes more incommensurate as x increases in accordance with the two band model. At xC=0.037 we have found temperature dependent, resolution limited elastic scattering at 4 incommensurate wave vectors Q=(1 δ1,2, 0, 0)*2π/a, which correspond to 2 SDWs with Neel temperatures of 19 K and 300 K. Our neutron diffraction measurements indicate that the electronic structure of Cr is robust, and that tuning Cr to its QCP results not in the suppression of antiferromagnetism, but instead enables new spin ordering due to novel nesting of the Fermi surface of Cr.

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Neutron diffraction in a model itinerant metal near a quantum critical point

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