There is provided a light-emitting device capable of suppressing a decrease in a light emission amount. A light-emitting device including a container member including a ceramic package provided with a depressed portion serving as a discharge space, and a light transmitting member which is attached to the ceramic package via a joining layer formed of a joining material so as to close the depressed portion; an inert gas encapsulated inside the discharge space; and a couple of discharge electrodes which are disposed in the depressed portion of the ceramic package so as to be spaced from each other, the joining material including glass exhibiting a white color, and oxide ceramic powder.

A cathodoluminescent lamp includes a filament configured to emit electrons responsive to a voltage applied across the filament, an anode configured to receive electrons emitted from the filament, an emitter comprising cathodoluminescent material, disposed in proximity to the anode, configured to emit photons responsive to stimulation from the electrons and a vacuum envelope configured to enclose the filament, anode, and emitter, and to maintain a vacuum over a path of the electrons. The filament comprises a smooth electron emitting surface. The cathodoluminescent material may comprise a semiconductor material.

The present invention relates to a lamp having synthetic ceramic glass electrodes, which comprises a glass tube, a plurality of synthetic ceramic glass electrodes, and a plurality of connecting members. The plurality of connecting members are disposed between the glass tube and the plurality of synthetic ceramic glass electrodes. The plurality of connecting members have different thermal expansion coefficients. Thereby, by using the plurality of connecting members to connect the plurality of synthetic ceramic glass electrodes, the glass tube and the plurality of synthetic ceramic glass electrodes can be sealed tightly.

The present invention relates to a lamp having synthetic ceramic glass electrodes, which comprises a glass tube, a plurality of synthetic ceramic glass electrodes, and a plurality of connecting members. The plurality of connecting members are disposed between the glass tube and the plurality of synthetic ceramic glass electrodes. The plurality of connecting members have different thermal expansion coefficients. Thereby, by using the plurality of connecting members to connect the plurality of synthetic ceramic glass electrodes, the glass tube and the plurality of synthetic ceramic glass electrodes can be sealed tightly.

A photoionization detector comprised of a gas discharge lamp that ionizes molecules of interest to create ionized molecules and electrons and a sensor having at least one opening for UV light to pass through and electrically conductive patterns on the top and bottom surfaces of the plate. A negative electrical potential pattern can be on one of the top or the bottom surface and can include an interior portion that is at least a first distance away from every edge of the at least one opening. An electron collecting electrode pattern can be on the other of the top or the bottom surface and can substantially fill an area surrounding the opening such that the negative electrical potential pattern and the electron collecting electrode pattern are offset relative to each other. The ionized molecules are collectable by a bias electrode and electrons are collectable by a collector electrode.

A photoionization detector sensor comprised of plate, at least one opening in the plate for UV light to pass through, and at least one electrically conductive pattern on at least one of the top and bottom surfaces of the plate. The at least one electrically conductive pattern can include a negative electrical potential pattern comprised of a first material. Further, the negative electrical potential pattern can have a void in its center, and the void can surround the at least one opening. The plate can be comprised of a second material that is different than the first material. The negative electrical potential pattern can be located on at least one of the top or the bottom surfaces, and the at least one electrically conductive pattern can further include an electron collecting electrode pattern on the other of top or bottom surface.