We determine the quantum ground-state properties of ultracold bosonic atoms interacting with the mode of a high-finesse resonator. The atoms are confined by an external optical lattice, whose period is incommensurate with the cavity mode wave length, and are driven by a transverse laser, which is resonant with the cavity mode. While for pointlike atoms photon scattering into the cavity is suppressed, for sufficiently strong lasers quantum fluctuations can support the build-up of an intracavity field, which in turn amplifies quantum fluctuations. The dynamics is described by a Bose-Hubbard model where the coefficients due to the cavity field depend on the atomic density at all lattice sites. Quantum Monte Carlo simulations and mean-field calculations show that for large parameter regions cavity backaction forces the atoms into clusters with a checkerboard density distribution. Here, the ground state lacks superfluidity and possesses finite compressibility, typical of a Bose-glass. This system constitutes a novel setting where quantum fluctuations give rise to effects usually associated with disorder.PACS numbers: 03.75. Hh, 05.30.Jp, 32.80.Qk, 42.50.Lc Bragg diffraction is a manifestation of the waveproperties of light and a powerful probe of the microscopic structure of a medium: Bragg peaks are intrinsically related to the existence of spatial order of the scatterers composing a medium and provide a criterion for the existence of long-range order [1]. Bragg diffraction of light by atoms in optical lattices has been measured for various geometries and settings, from gratings of laser-cooled atoms [2-5] to ultracold bosons in the Mott-Insulator (MI) phase [6]. In most of these setups the backaction of light on the atomic medium, due to the mechanical effects of atom-photon interactions, is usually negligible, while photon recoil can give rise to visible effects in the spectrum of the diffracted light [7].Recent work proposed to use high-finesse optical resonators to enhance light scattering into one spatial direction, increasing the collection efficiency and thereby suppressing diffusion related to photon scattering [8]. For appropriate geometries, properties of the medium's quantum state can be revealed by measuring the light at the cavity output [7,8]. These proposals assume that backaction of the cavity field on the atoms can be discarded. Such an assumption is, however, not valid in the regime considered in Refs. [9][10][11][12][13][14]: Here, the strong coupling between cavity and atoms can induce the formation of stable Bragg gratings in cold [9,10] and ultracold atomic gases [11][12][13][14] that coherently scatter light from a transverse laser into the cavity mode. This phenomenon occurs when the intensity of the pump exceeds a certain threshold [10,11,13,15]. At ultralow temperatures the self-organized medium is a supersolid [13], while for larger pump intensities incompressible phases are expected [16].Let us now assume that the atoms are inside a highfinesse standing-wave cavity and form a periodic ...
