Magnetic frustration is a key ingredient to prevent conventional ordering and, in combination with enhanced fluctuations in low dimensional quantum magnets, to stabilize the long sought spin liquid ground states. Most experimental spin liquid candidates inevitably deviate from perfectly frustrated models due to chemical and structural disorder, blurring the nature and origin of their ground states. Y-Kapellasite Y$_3$Cu$_9$(OH)$_{19}$Cl$_{8}$ realizes a chemically clean system with an underlying kagome sub-lattice. The crystals undergo the theoretically predicted magnetic in-plane (1/3 1/3) order from a subtle release of frustration due to a distortion of the kagome system realised by displaced Y atoms. By studying the effect of pressure on the structure and optical phonons, we show that this distortion is partially lifted by compression towards a more isotropic model of interactions, in a gradual manner, without structural transition. Using $\mu$SR, we further show that the magnetic ground state is surprisingly sensitive to the applied pressure for a mineral, and that under a moderate 2 GPa pressure, the frustration increase is sufficient to induce a fluctuating ground state. Suppressing long-range magnetic order via frustration tuning with pressure, in an ultraclean material, establishes a major step towards realizing a well-controlled spin liquid ground state.
Comment: 18 pages, 11 figures