Abstract: A gas-discharge lamp (deuterium lamp) is provided having a lamp bulb (26) filled with gas, an anode (12) disposed inside the lamp bulb, a cathode (10) spaced from the anode inside the lamp bulb, a housing having a molded body (18), a rear housing wall (24), and a housing base made at least partially of electrically nonconductive material. The housing base includes a housing front (16), an intermediate housing wall (22), a cathode space (28), and a cathode shielding window (20). The cathode shielding window is insulated from the molded body and/or is made of an insulating material. The gas-discharge lamp is particularly applicable for analytical purposes.

Abstract: A gas-discharge lamp (deuterium lamp) is provided having a lamp bulb (26) filled with gas, an anode (12) disposed inside the lamp bulb, a cathode (10) spaced from the anode inside the lamp bulb, a housing having a molded body (18), a rear housing wall (24), and a housing base made at least partially of electrically nonconductive material. The housing base includes a housing front (16), an intermediate housing wall (22), a cathode space (28), and a cathode shielding window (20). The cathode shielding window is insulated from the molded body and/or is made of an insulating material. The gas-discharge lamp is particularly applicable for analytical purposes.

Abstract: A method is provided for operating an amalgam lamp, wherein the amalgam lamp has an emitter tube filled with inert gas. The amalgam is heated in the emitter tube by an external energy source. The amalgam lamp has an amalgam deposit.

Abstract: For insertion into a lamp housing, a radiator module (1) is provided inside of the module with at least one discharge lamp as radiation source, which puts out an ultraviolet radiation produced by plasma within a discharge chamber (2), the plasma being formed by coupling an electromagnetic field into the discharge chamber (2) and the radiation produced by the plasma exits along a given optical axis through at least one body (12) transparent to ultraviolet radiation as a window. In the range of the plasma at least one diaphragm opaque to radiation is provided with a through-bore along the axis (6), an additional thermal radiation source is fixedly arranged in a given position within the module along the optical axis (6); the additionally produced radiation penetrates through a second transparent body (13) as entry window into the discharge chamber, and then exits along the axis through the first transparent body (12) together with the ultraviolet radiation produced by the plasma.

Abstract: For insertion into a lamp housing, a radiator module (1) is provided inside of the module with at least one discharge lamp as radiation source, which puts out an ultraviolet radiation produced by plasma within a discharge chamber (2), the plasma being formed by coupling an electromagnetic field into the discharge chamber (2) and the radiation produced by the plasma exits along a given optical axis through at least one body (12) transparent to ultraviolet radiation as a window. In the range of the plasma at least one diaphragm opaque to radiation is provided with a through-bore along the axis (6), an additional thermal radiation source is fixedly arranged in a given position within the module along the optical axis (6); the additionally produced radiation penetrates through a second transparent body (13) as entry window into the discharge chamber, and then exits along the axis through the first transparent body (12) together with the ultraviolet radiation produced by the plasma.