A product having at least one plasma lamp that includes plates that are approximately parallel, with at least one array of microcavities formed in a surface of at least one plate. When desirable, the plates are separated a fixed distance by spacers with at least one spacer being placed near the plate's edge to form a hermetic seal therewith. A gas makes contact with the microcavity array. Electrodes capable of delivering a time-varying voltage are located such that the application of the time-varying voltage interacts with the gas to form a glow discharge plasma in the microcavities and the fixed volume between the plates. The glow discharge plasma efficiently and uniformly emits radiation that is predominantly in the UV/VUV spectral range with at least a portion of the radiation being emitted from the plasma lamp.

A plasma lamp includes plates that are approximately parallel, with at least one array of microcavities formed in a surface of at least one plate. When desirable, the plates are separated a fixed distance by spacers with at least one spacer being placed near the plate's edge to form a hermetic seal therewith. A gas makes contact with the microcavity array. Electrodes capable of delivering a time-varying voltage are located on the surface of each plate. At least one electrode is located on an exterior surface of at least one interior plate. Optionally, protective windows may be placed over the electrodes. The application of the time-varying voltage interacts with the gas to form a glow discharge plasma in the microcavities and the fixed volume between the plates (when present). The glow discharge plasma efficiently and uniformly emits UV/VUV radiation over the entire surface of the lamp.

A plasma lamp includes plates that are approximately parallel, with at least one array of microcavities formed in a surface of at least one plate. When desirable, the plates are separated a fixed distance by spacers with at least one spacer being placed near the plate's edge to form a hermetic seal therewith. A gas makes contact with the microcavity array. Electrodes capable of delivering a time-varying voltage are located on the surface of each plate. At least one electrode is located on an exterior surface of at least one interior plate. Optionally, protective windows may be placed over the electrodes. The application of the time-varying voltage interacts with the gas to form a glow discharge plasma in the microcavities and the fixed volume between the plates (when present). The glow discharge plasma efficiently and uniformly emits UV/VUV radiation over the entire surface of the lamp.

A method and apparatus for forming a flowable film are described. The method includes providing an oxygen free precursor gas mixture to a processing chamber containing a substrate. The oxygen free precursor gas is activated by exposure to UV radiation in the processing chamber. Molecular fragments resulting from the UV activation are encouraged to deposit on the substrate to form a flowable film on the substrate. The substrate may be cooled to encourage deposition. The film may be hardened by heating and/or by further exposure to UV radiation.

A method and apparatus for forming a flowable film are described. The method includes providing an oxygen free precursor gas mixture to a processing chamber containing a substrate. The oxygen free precursor gas is activated by exposure to UV radiation in the processing chamber. Molecular fragments resulting from the UV activation are encouraged to deposit on the substrate to form a flowable film on the substrate. The substrate may be cooled to encourage deposition. The film may be hardened by heating and/or by further exposure to UV radiation.

A plasma lamp includes plates that are approximately parallel, with at least one array of microcavities formed in a surface of at least one plate. When desirable, the plates are separated a fixed distance by spacers with at least one spacer being placed near the plate's edge to form a hermetic seal therewith. A gas makes contact with the microcavity array. Electrodes capable of delivering a time-varying voltage are located on the surface of each plate. At least one electrode is located on an exterior surface of at least one interior plate. Optionally, protective windows may be placed over the electrodes. The application of the time-varying voltage interacts with the gas to form a glow discharge plasma in the microcavities and the fixed volume between the plates (when present). The glow discharge plasma efficiently and uniformly emits UV/VUV radiation over the entire surface of the lamp.

A method and apparatus for forming a flowable film are described. The method includes providing an oxygen free precursor gas mixture to a processing chamber containing a substrate. The oxygen free precursor gas is activated by exposure to UV radiation in the processing chamber. Molecular fragments resulting from the UV activation are encouraged to deposit on the substrate to form a flowable film on the substrate. The substrate may be cooled to encourage deposition. The film may be hardened by heating and/or by further exposure to UV radiation.