Abstract: A plasma generation device includes: a substrate having a first surface and a second surface; a stripline resonant ring disposed on the first surface of the substrate, and defining a discharge gap; a pair of electrode extensions connected to the stripline resonant ring at the discharge gap; a ground plane disposed on the second surface of the substrate; a gas flow element configured to flow gas between at least one of: (1) the discharge gap, and (2) the pair of electrode extensions; and a structure disposed adjacent the substrate to form an enclosure that substantially encloses at least a region including the discharge gap and the electrode extensions, the enclosure being adapted to contain a plasma.

Abstract: An ionization device comprises: a plasma source configured to generate a plasma. The plasma comprises light, plasma ions and plasma electrons. The plasma source comprises an aperture disposed such that at least part of the light passes through the aperture and is incident on a gas sample. The ionization device further comprises an ionization region; and a plasma deflection device comprising a plurality of electrodes configured to establish an electric field, wherein the electric field substantially prevents the plasma ions from entering the ionization region.

Abstract: Ionization devices that have at least two modes of ionization, and that can switch between these two modes of operation, are described. Illustratively, the ionization devices can switch between a photoionization (PI) mode and a combined mode of electroionization (EI) and PI (EI/PI mode).

Abstract: An ionization device comprises: a plasma source configured to generate a plasma. The plasma comprises light, plasma ions and plasma electrons. The plasma source comprises an aperture disposed such that at least part of the light passes through the aperture and is incident on a gas sample. The ionization device further comprises an ionization region; and a plasma deflection device comprising a plurality of electrodes configured to establish an electric field, wherein the electric field substantially prevents the plasma ions from entering the ionization region.

Abstract: A device includes a first substrate having a principal surface having a plurality of sample sites having a corresponding sample; a second substrate having a principal surface facing and spaced apart from the principal surface of the first substrate, the second substrate having a plurality of ultraviolet emission sites corresponding to the sample sites of the first substrate, each of the ultraviolet emission sites being spaced apart from and facing a corresponding one of the sample sites of the first substrate, each of the ultraviolet emission sites being configured to emit ultraviolet light to a corresponding one of the sample sites on the first substrate, and to ionize at least a portion of a sample provided at each sample site; and an ion extraction device configured to extract ions from a gap between the first substrate and the structure.

Abstract: A device includes a first substrate having a principal surface having a plurality of sample sites having a corresponding sample; a second substrate having a principal surface facing and spaced apart from the principal surface of the first substrate, the second substrate having a plurality of ultraviolet emission sites corresponding to the sample sites of the first substrate, each of the ultraviolet emission sites being spaced apart from and facing a corresponding one of the sample sites of the first substrate, each of the ultraviolet emission sites being configured to emit ultraviolet light to a corresponding one of the sample sites on the first substrate, and to ionize at least a portion of a sample provided at each sample site; and an ion extraction device configured to extract ions from a gap between the first substrate and the structure.

Abstract: A plasma generation device includes: a substrate having a first surface and a second surface; a stripline resonant ring disposed on the first surface of the substrate, and defining a discharge gap; a pair of electrode extensions connected to the stripline resonant ring at the discharge gap; a ground plane disposed on the second surface of the substrate; a gas flow element configured to flow gas between at least one of: (1) the discharge gap, and (2) the pair of electrode extensions; and a structure disposed adjacent the substrate to form an enclosure that substantially encloses at least a region including the discharge gap and the electrode extensions, the enclosure being adapted to contain a plasma.

Abstract: An illumination device provides light to a flowing gaseous sample. The device includes a structure including a cavity configured to have a microplasma disposed therein. The cavity substantially encircles a cross-section of a channel that is configured to pass the flowing gaseous sample therethrough. The cavity is defined in part by an interior wall of the structure separating the cavity from the channel. The interior wall includes at least one orifice passing therethrough configured to provide to the flowing gaseous sample light generated by the microplasma. At least one electrode is configured to supply energy to the microplasma within the cavity.