A laser-sustained broadband light source includes a gas containment structure and multiple jet nozzles. The jet nozzles are configured to direct multiple liquid jets of plasma-forming material in directions to collide with one another within the gas containment structure. The laser-sustained broadband light source further includes a laser pump source configured to generate an optical pump to sustain a plasma in a region of the gas containment structure at a collision point of the plurality of liquid jets and a light collector element configured to collect broadband light emitted from the plasma.

A rare gas lamp device is disclosed. The rare gas lamp device includes: a lamp body provided in a shape of a cylinder to contain a rare gas and a fluorescent material for emitting light; a plurality of cap electrodes fixed to both ends of the lamp body; a plurality of band electrodes extending in a length direction from the plurality of cap electrodes and arranged opposite to each other with respect to a center axis of the lamp body, and positioned on a circumferential surface of the lamp body, wherein a light-emitting area of the lamp body is an exposed surface of the circumferential surface of the lamp body between the plurality of band electrodes; a spring holder coupled with each of the plurality of cap electrodes and configured to apply a voltage to the band electrodes through the plurality of cap electrodes, the spring holder including a first fixing part configured to support a first side of the cap electrode, a second fixing part configured to support a second side of the cap electrode, and an inserting opening formed between a first end of the first fixing part and a first end of the second fixing part such that the cap electrode is inserted in the inserting opening; and a stopper protruding from each of the plurality of cap electrodes, wherein, when each of the plural of cap electrodes is inserted through the inserting opening, the stopper is interfered by the first end of the first fixing part or the first end of the second fixing part to restrict the light-emitting area from rotating about the center axis of the lamp body.

An apparatus for artificial weathering or lightfastness testing of samples or for simulating solar radiation, the apparatus comprises a weathering chamber, an electrodeless lamp provided in the weathering chamber and comprising a bulb filled with a composition that emits light when in a plasma state, and a radio frequency source being arranged so that it radiate a radio frequency field into the bulb to generate a luminous plasma for emitting a radiation comprising spectral emission characteristics similar to natural solar radiation.

A rare gas lamp device is disclosed. The rare gas lamp device includes: a lamp body provided in a shape of a cylinder to contain a rare gas and a fluorescent material for emitting light; a plurality of cap electrodes fixed to both ends of the lamp body; a plurality of band electrodes extending in a length direction from the plurality of cap electrodes and arranged opposite to each other with respect to a center axis of the lamp body, and positioned on a circumferential surface of the lamp body, wherein a light-emitting area of the lamp body is an exposed surface of the circumferential surface of the lamp body between the plurality of band electrodes; a spring holder coupled with each of the plurality of cap electrodes and configured to apply a voltage to the band electrodes through the plurality of cap electrodes, the spring holder including a first fixing part configured to support a first side of the cap electrode, a second fixing part configured to support a second side of the cap electrode, and an inserting opening formed between a first end of the first fixing part and a first end of the second fixing part such that the cap electrode is inserted in the inserting opening; and a stopper protruding from each of the plurality of cap electrodes, wherein, when each of the plural of cap electrodes is inserted through the inserting opening, the stopper is interfered by the first end of the first fixing part or the first end of the second fixing part to restrict the light-emitting area from rotating about the center axis of the lamp body.

The invention relates to a phosphor for a UV emitting device, having the formula Na.sub.1+xCa.sub.1−2xPO.sub.4:PR3.sup.+.sub.x wherein 0<x<0.5.

There is provided a light transmissive material capable of reducing the attachment of contaminants to its front surface, and easily removing contaminants even when the contaminants have been attached thereto. There are also provided a lamp including alight emitting tube formed of the light transmissive material as well as a gas treatment device and a gas treatment method utilizing the light transmissive material.

The light transmissive material according to the present invention includes a glass substrate having a front surface on which a surface layer formed of nano-silica particles is provided. The lamp according to the present invention includes a light emitting tube formed of the above-described light transmissive material, in which the surface layer is provided on an outer surface of the light emitting tube. The gas treatment device according to the present invention includes: a chamber having a treatment space through which a gas to be treated flows; and an ultraviolet lamp disposed so that at least a part of a light emitting tube is exposed to the treatment space. The light emitting tube in the ultraviolet lamp has an outer surface on which a surface layer formed of nano-silica particles is provided.

A transmission line for conveying a radio frequency (RF) signal between a first terminal and a second terminal. The transmission line comprises an inner conductor, a middle conductor and an outer conductor. The inner conductor comprises a length of conductive material having a first end for electrical connection with the first terminal and a second end for electrical connection with the second terminal. The middle conductor surrounds at least a part of the length of the inner conductor and is electrically connected to the electrical ground of the source. The outer conductor surrounds at least a part of the length of the middle conductor and is electrically connected to the electrical ground of the load.

There is provided an electrodeless plasma lamp and confinement member for an electrodeless plasma lamp. The lamp comprises a lamp body with an input coupling element, with one end coupled to an RF source and the other end coupled to a first ground potential. An output coupling element is received substantially within the lamp body and spaced apart from the input coupling element and from the top of the lamp body, wherein one end of the output coupling element is coupled to a second ground potential and the other end of the output coupling element at the top of the lamp body is coupled to a gas filled vessel. An electromagnetic confinement member extends away from the lamp body and surrounds it for reducing emission of electromagnetic waves below a predetermined threshold frequency, and includes a plurality of apertures formed therein.

A high brightness laser-sustained broadband light source includes a gas containment structure and a pump laser configured to generate a pump beam including illumination of a wavelength at least proximate to a weak absorption line of a neutral gas contained in the gas containment structure. The broadband light source includes one or more anamorphic illumination optics configured to focus the pump beam into an approximately elliptical beam waist positioned in or proximate to the center of the gas containment structure. The broadband light source includes one or more first collection optics configured to collect broadband radiation emitted by the plasma in a direction substantially aligned with a longer axis of the elliptical beam waist.

A system for pumping laser sustained plasma and enhancing one or more selected wavelengths of output illumination generated by the laser sustained plasma is disclosed. In embodiments, the system includes one or more pump modules configured to generate pump illumination for the laser sustained plasma and one or more enhancing illumination sources configured to generate enhancing illumination at one or more selected wavelengths. The pump illumination may be directed along one or more pump illumination paths that are non-collinear to an output illumination path of the output illumination. The enhancing illumination may be directed along an illumination path that is collinear to the output illumination path of the output illumination so that the enhancing illumination is combined with the output illumination, thereby enhancing the output illumination at the one or more selected wavelengths.