Quantum critical fluctuations generate intensely magnetic field-resilient superconductivity in UTe2

Quantum critical phase boundaries (QCPBs) -- where a continuous phase transition occurs at zero temperature -- have been found to nucleate novel electronic states in a number of strongly correlated materials. Emergent electronic phases, such as unconventional superconductivity, frequently occur in close proximity to a QCPB. However, the antagonism between magnetic field and superconductivity generally suppresses such superconductive phases to modest magnetic field ranges, except in notable cases such as the high-$T_\text{c}$ cuprates. Here we show that the heavy fermion Kondo-lattice system UTe$_2$ possesses a QCPB at remarkably high magnetic fields $\sim$ 50 T, underpinning an extremely high field superconducting state that persists to fields $> \sim$ 70 T despite its relatively modest transition temperature of $T_\text{c} \approx$ 2 K. Whereas previous studies found this superconducting state to exist exclusively inside a field-polarised paramagnetic host-phase accessed following a first-order metamagnetic transition, for magnetic field tilt angles in the rotation plane connecting the reciprocal (010) and (101) vectors, we find an extended region of this superconductivity outside the field-polarised state. In this special rotation plane we also observe a pronounced suppression of the metamagnetic transition towards zero temperature, revealing that the metamagnetic transition surface ends at a QCPB. The superconducting $T_\text{c}$ exhibits a strong angular dependence and is enhanced close to the QCPB, where the onset of superconductivity is stretched over a surprisingly large magnetic field range reaching as low as 30 T. We model our data by a phenomenological Ginzburg-Landau theory, and show how an extended quantum critical line -- rather than a more conventional QCPB at a singular point -- anchors the remarkable high magnetic field phase landscape of UTe$_2$.