Superfluidity is a manifestation of the operation of the laws of quantum mechanics on a macroscopic scale. The conditions under which superfluidity becomes manifest have been extensively explored experimentally in both quantum liquids (liquid 4 He being the canonical example) and ultra-cold atomic gases ( 1, 2), including as a function of dimensionality ( 3,4). Of particular interest is the hitherto unresolved question whether a solid can be superfluid ( 5,6). Here we report the identification of a new state of quantum matter with intertwined superfluid and density wave order in a system of twodimensional bosons subject to a triangular lattice potential. Using a torsional oscillator we have measured the superfluid response of the second atomic layer of 4 He adsorbed on the surface of graphite, over a wide temperature range down to 2 mK. Superfluidity is observed over a narrow range of film densities, emerging suddenly and subsequently collapsing towards a quantum critical point. The unusual temperature dependence of the superfluid density in the limit of zero temperature and the absence of a clear superfluid onset temperature are explained, self-consistently, by an ansatz for the excitation spectrum, reflecting density wave order, and a quasi-condensate wavefunction breaking both gauge and translational symmetry.2 Superfluid 4 He is described by a condensate wavefunction, with long-range coherence of the global phase () r , determining the quantum hydrodynamic and nonclassical rotation properties ( 1,2). In two dimensions (2D) the superfluid state has power law correlations of the local phase ( 4,7,8). While in bulk the destruction of superfluidity at finite transition temperature arises from the creation of thermal excitations (phonons and rotons), in two dimensions topological excitations (vortices) play a crucial role. In this case the quasicondensate is suddenly destroyed at the Berezinskii-Kosterlitz-Thouless (BKT) phase transition by the unbinding of vortex-antivortex pairs, accompanied by a universal jump in superfluid density ( 3, 7). On the other hand superfluidity may be destroyed at a T = 0 quantum phase transition by increasing correlations or disorder. Here the classic example is the superfluid -Mott insulator transition ( 9), which has been observed in cold bosonic atoms in optical lattices ( 10, 11), by tuning the periodic potential.The novelty of the putative supersolid is that it manifests both superfluid and density wave order ( 12). Unambiguous detection has proved elusive in bulk solid 4 He ( 6, 13) , where a variety of scenarios have been proposed to establish superfluidity coexisting with solid order. These involve mobile zero-point vacancies, frozen-in dislocations and disorder ( 14,15), and the defects determine the strength of the superfluid response. Supersolids have been predicted on model 2D quantum lattices, again arising from mobile vacancies and favoured by triangular lattice symmetry ( 16). Several schemes to realize supersolids in ultracold atoms have also been proposed ( 17, 1...
