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Electron Mass Enhancement near a Nematic Quantum Critical Point in NaFe_(1-x)Co_(x)As

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arxiv 1810.08777 v1 pith:B42LF5IZ submitted 2018-10-20 cond-mat.supr-con cond-mat.str-el

Electron Mass Enhancement near a Nematic Quantum Critical Point in NaFe_(1-x)Co_(x)As

classification cond-mat.supr-con cond-mat.str-el
keywords nematicmagneticcriticalquantumarounddopingelectronlambda
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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A magnetic order can be completely suppressed at zero temperature($T$), by doping carriers or applying pressure, at a quantum critical point(QCP), around which physical properties change drastically. However, the situation is unclear for an electronic nematic order that breaks rotation symmetry. Here we report nuclear magnetic resonance(NMR) studies on NaFe$_{1-x}$Co$_{x}$As where magnetic and nematic transitions are well separated. The NMR spectrum is sensitive to inhomogeneous magnetic fields in the vortex state, which is related to London penetration depth $\lambda_{\rm L}$ that measures the electron mass $m^*$. We discovered two peaks in the doping dependence of $\lambda_{\rm L}^2$($T\sim$0); one at $x_{\rm M}$=0.027 where the spin-lattice relaxation rate shows quantum critical behavior, and another at $x_{\rm c}$=0.032 around which the nematic transition temperature extrapolates to zero and the electrical resistivity shows a $T$-linear variation. Our results indicate that a nematic QCP lies beneath the superconducting dome at $x_{\rm c}$ where $m^*$ is enhanced. The impact of the nematic fluctuations on superconductivity is discussed.

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