One-dimensional electronic systems are characterized by strong charge and spin fluctuations, which due to coupling between individual wires in real systems lead to instabilities into various ordered phases at sufficiently low temperatures. Especially interesting are the cases where quasi-one-dimensional systems before superconducting, since the superconducting order parameter can have different symmetries. In this master’s thesis I focused on a recently discovered system Cs\textsubscript{2}Mo\textsubscript{3}As\textsubscript{3}, in which Mo and As atoms form conductive “nanowires” along the crystallographic $c$-axis. The material is superconducting below a relatively high critical temperature $T_\mathrm{c} = 11.5~\text{K}$ – the highest among the known quasi-one-dimensional superconductors. I attempted to determine the superconducting order parameter symmetry using muon spin relaxation (\textmu SR) in a weak field perpendicular to the initial polarisation of muon spins. In both the normal and superconducting state the muon signal shows characteristic oscillations due to the Larmor precession of the muon magnetic moments, which is additionally dampened in the superconducting state. I ascribed this Gaussian-shaped damping to the formation of a vortex lattice, which significantly broadens the static field distribution in which the muons precess. The comparison of different order parameter symmetries, where I considered the $s$-, $p$-, $d$-symmetries, showed best agreement for scenarios with $s$- and $p$- symmetry and significantly worse agreement for the third option. From the analyses I also determined the magnitude of the order parameter at zero temperature $\Delta_0$ and calculated the ratios $2\Delta_0/k_\mathrm{B}T_\mathrm{c} = 4.57(1)$ in $5.98(1)$ fort he $s$- and $p$- symmetry models, respectively. The presented \textmu SR data cannot unambiguously determine the nature of the superconducting state of Cs\textsubscript{2}Mo\textsubscript{3}As\textsubscript{3}, but have nevertheless shown that this case of superconductivity cannot be described simply by the standard Bardeen-Cooper-Schrieffer theory.
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