Triangular lattice magnet GdGa2 with short-period spin cycloids and possible skyrmion phases
Abstract
The two-dimensional triangular lattice (TAL) is a model system of magnetic frustration and competing interactions, where skyrmion spin vortices can be induced by a vertical magnetic field B. We target the binary compound GdGa2 with an undistorted TAL of Gd3+ Heisenberg moments. At higher temperature (T > 5 K, B = 0, phase II), we reveal the cycloidal spin textures in GdGa2 via resonant elastic X-ray scattering (REXS). Further, a transition with strong magneto-elastic response occurs when cooling into the zero-field ground state (T < 5 K, phase I). We also report the thermodynamic phase boundaries of B-induced magnetic A-phases, which are suppressed by an in-plane magnetic field and which have enhanced resistivity due to the partial opening of a charge gap. In analogy to Gd2PdSi3 and GdRu2Si2, these phases may represent a superposition of various cycloids, possibly a N\'eel skyrmion lattice. Our work lays the basis for further studies of the magnetic phase diagram of GdGa2.
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