Two dimensional nature of superconductivity in intercalated layered systems LixHfNCl and LixZrNCl: muon spin relaxation and magnetization measurements

Abstract

We report muon spin relaxation (μSR) and magnetization measurements, together with synthesis and characterization, of the Li-intercalated layered superconductors LixHfNCl and LixZrNCl with/without co-intercalation of THF (tetrahydrofuran) or PC (propylene carbonate). The 3-dimensional (3-d) superfluid density ns/m* (superconducting carrier density / effective mass), as well as the two dimensional superfluid density ns2d/m*ab (2-dimensional (2-d) area density of superconducting carriers / ab-plane effective mass), have been derived from the μSR results of the magnetic-field penetration depth λab observed with external magnetic field applied perpendicular to the 2-d honeycomb layer of HfN / ZrN. In a plot of Tc versus ns2d/m*ab, most of the results lie close to the linear relationship found for underdoped high-Tc cuprate (HTSC) and layered organic BEDT superconductors. In LixZrNCl without THF intercalation, the superfluid density and Tc for x = 0.17 and 0.4 do not show much difference, reminiscent of μSR results for some overdoped HTSC systems. Together with the absence of dependence of Tc on average interlayer distance among ZrN / HfN layers, these results suggest that the 2-d superfluid density ns2d/m*ab is a dominant determining factor for Tc in the intercalated nitride-chloride systems. We also report μSR and magnetization results on depinning of flux vortices, and the magnetization results for the upper critical field Hc2 and the penetration depth λ. Reasonable agreement was obtained between μSR and magnetization estimates of λ. We discuss the two dimensional nature of superconductivity in the nitride-chloride systems based on these results.

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