Observation of non-Fermi liquid behavior in hole-doped LiFe1-x VxAs

L. Y. Xing; X. Shi; P. Richard; X. C. Wang; Q. Q. Liu; B. Q. Lv; J. Z. Ma; B. B. Fu; L. Y. Kong; H. Miao; T. Qian; T. K. Kim; M. Hoesch; H. Ding; C. Q. Jin

doi:10.1103/PhysRevB.94.094524

Observation of non-Fermi liquid behavior in hole-doped LiFe1-x VxAs

L. Y. Xing, X. Shi, P. Richard, X. C. Wang, Q. Q. Liu, B. Q. Lv, J. Z. Ma, B. B. Fu, L. Y. Kong, H. Miao, T. Qian, T. K. Kim, M. Hoesch, H. Ding, C. Q. Jin

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12 Scopus citations

Abstract

We synthesized a series of V-doped LiFe1-xVxAs single crystals. The superconducting transition temperature Tc of LiFeAs decreases rapidly at a rate of 7 K per 1% V. The Hall coefficient of LiFeAs switches from negative to positive with 4.2% V doping, showing that V doping introduces hole carriers. This observation is further confirmed by the evaluation of the Fermi surface volume measured by angle-resolved photoemission spectroscopy (ARPES), from which a 0.3 hole doping per V atom introduced is deduced. Interestingly, the introduction of holes does not follow a rigid band shift. We also show that the temperature evolution of the electrical resistivity as a function of doping is consistent with a crossover from a Fermi liquid to a non-Fermi liquid. Our ARPES data indicate that the non-Fermi liquid behavior is mostly enhanced when one of the hole dxz/dyz Fermi surfaces is well nested by the antiferromagnetic wave vector to the inner electron Fermi surface pocket with the dxy orbital character. The magnetic susceptibility of LiFe1-xVxAs suggests the presence of strong magnetic impurities following V doping, thus providing a natural explanation to the rapid suppression of superconductivity upon V doping.

Original language	English
Article number	094524
Journal	Physical Review B
Volume	94
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevB.94.094524
State	Published - Sep 28 2016
Externally published	Yes

Funding

We acknowledge Jiang-Ping Hu for useful discussions. This work was supported by grants from MOST (No. 2011CBA001000, No. 2011CBA00102, No. 2012CB821403, No. 2013CB921700, and No. 2015CB921301) and NSFC (No. 11674371, No. 11004232, No. 11034011/A0402, No. 11234014, No. 11274362, No. 11474330, and No. 11474344) of China. We acknowledge Diamond Light Source for time on beamline I05 under Proposal No. SI11452.

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@article{bffd845eb1004b2185938d027a189372,

title = "Observation of non-Fermi liquid behavior in hole-doped LiFe1-x VxAs",

abstract = "We synthesized a series of V-doped LiFe1-xVxAs single crystals. The superconducting transition temperature Tc of LiFeAs decreases rapidly at a rate of 7 K per 1% V. The Hall coefficient of LiFeAs switches from negative to positive with 4.2% V doping, showing that V doping introduces hole carriers. This observation is further confirmed by the evaluation of the Fermi surface volume measured by angle-resolved photoemission spectroscopy (ARPES), from which a 0.3 hole doping per V atom introduced is deduced. Interestingly, the introduction of holes does not follow a rigid band shift. We also show that the temperature evolution of the electrical resistivity as a function of doping is consistent with a crossover from a Fermi liquid to a non-Fermi liquid. Our ARPES data indicate that the non-Fermi liquid behavior is mostly enhanced when one of the hole dxz/dyz Fermi surfaces is well nested by the antiferromagnetic wave vector to the inner electron Fermi surface pocket with the dxy orbital character. The magnetic susceptibility of LiFe1-xVxAs suggests the presence of strong magnetic impurities following V doping, thus providing a natural explanation to the rapid suppression of superconductivity upon V doping.",

author = "Xing, {L. Y.} and X. Shi and P. Richard and Wang, {X. C.} and Liu, {Q. Q.} and Lv, {B. Q.} and Ma, {J. Z.} and Fu, {B. B.} and Kong, {L. Y.} and H. Miao and T. Qian and Kim, {T. K.} and M. Hoesch and H. Ding and Jin, {C. Q.}",

note = "Publisher Copyright: {\textcopyright} 2016 American Physical Society.",

year = "2016",

month = sep,

day = "28",

doi = "10.1103/PhysRevB.94.094524",

language = "English",

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T1 - Observation of non-Fermi liquid behavior in hole-doped LiFe1-x VxAs

AU - Xing, L. Y.

AU - Shi, X.

AU - Richard, P.

AU - Wang, X. C.

AU - Liu, Q. Q.

AU - Lv, B. Q.

AU - Ma, J. Z.

AU - Fu, B. B.

AU - Kong, L. Y.

AU - Miao, H.

AU - Qian, T.

AU - Kim, T. K.

AU - Hoesch, M.

AU - Ding, H.

AU - Jin, C. Q.

PY - 2016/9/28

Y1 - 2016/9/28

N2 - We synthesized a series of V-doped LiFe1-xVxAs single crystals. The superconducting transition temperature Tc of LiFeAs decreases rapidly at a rate of 7 K per 1% V. The Hall coefficient of LiFeAs switches from negative to positive with 4.2% V doping, showing that V doping introduces hole carriers. This observation is further confirmed by the evaluation of the Fermi surface volume measured by angle-resolved photoemission spectroscopy (ARPES), from which a 0.3 hole doping per V atom introduced is deduced. Interestingly, the introduction of holes does not follow a rigid band shift. We also show that the temperature evolution of the electrical resistivity as a function of doping is consistent with a crossover from a Fermi liquid to a non-Fermi liquid. Our ARPES data indicate that the non-Fermi liquid behavior is mostly enhanced when one of the hole dxz/dyz Fermi surfaces is well nested by the antiferromagnetic wave vector to the inner electron Fermi surface pocket with the dxy orbital character. The magnetic susceptibility of LiFe1-xVxAs suggests the presence of strong magnetic impurities following V doping, thus providing a natural explanation to the rapid suppression of superconductivity upon V doping.

AB - We synthesized a series of V-doped LiFe1-xVxAs single crystals. The superconducting transition temperature Tc of LiFeAs decreases rapidly at a rate of 7 K per 1% V. The Hall coefficient of LiFeAs switches from negative to positive with 4.2% V doping, showing that V doping introduces hole carriers. This observation is further confirmed by the evaluation of the Fermi surface volume measured by angle-resolved photoemission spectroscopy (ARPES), from which a 0.3 hole doping per V atom introduced is deduced. Interestingly, the introduction of holes does not follow a rigid band shift. We also show that the temperature evolution of the electrical resistivity as a function of doping is consistent with a crossover from a Fermi liquid to a non-Fermi liquid. Our ARPES data indicate that the non-Fermi liquid behavior is mostly enhanced when one of the hole dxz/dyz Fermi surfaces is well nested by the antiferromagnetic wave vector to the inner electron Fermi surface pocket with the dxy orbital character. The magnetic susceptibility of LiFe1-xVxAs suggests the presence of strong magnetic impurities following V doping, thus providing a natural explanation to the rapid suppression of superconductivity upon V doping.

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Observation of non-Fermi liquid behavior in hole-doped LiFe1-x VxAs

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