Abstract: The electrode consists of a metal carrier (1) and a surface layer (3), which has been deposited on the carrier and has a thickness of 0.1 to 20 .mu.m and consists of a material which differs from the carrier material and distinguishes from the carrier material by having a smaller work function and lower thermal and electrical conductivities and is selected from the group tungsten, niobium, tantalum, rhenium and chromium. The carrier (1) consists of a deeply drawable material. There is preferably also an interlayer (2) made of a highly conductive metal.

Abstract: A surface for electrical discharge for incorporation in a gas discharge chamber and designed to produce a uniform distribution of the field strength factor, and an increase in the photon and/or the electron density. This is achieved by employing a microstructure combining at least two materials of different physical properties and having a geometry which increases electron emission.

Abstract: A TE laser amplifier has a fully closed metal housing. This fact, its geometry, and that of its electrodes (5-7) and/or the reversal of the output polarity make possible a homogenous field distribution, a capability to influence the local amplification process in the laser medium, and a relatively long lifetime of the gas and the laser.

Abstract: In electrically pumped CO.sub.2 gas lasers, there take place widely different chemical and physical processes which lead, at least partially, to undesirable interactions of the gases among themselves, and/or of the gases with the electrical and/or the optical field and/or with the materials used in the gas-filled chambers. Bodies that are equipped with surface area-enlarging structures are included in the discharge or resonator chamber or in adjacent secondary chambers. The secondary chambers by themselves act as reservoirs or as carriers of reservoirs for suitable catalysts and gas components and/or the heating of the catalysts, and have a predetermined influence over the conditions of volume and/or pressure and/or temperature. The inclusion of such secondary chambers and such structures which enlarge surface area inside the chambers make possible the attainment of at least an approximate state of equilibrium, which leads to uniformly good discharge and long life with high laser efficiency.

Abstract: Methods and apparatuses for operating a gas laser which utilize the electrical discharge between the electrodes to increase gas circulation. In a first embodiment, electrical discharges cause a control current (pulse) which activates an electromechanical device disposed within a closed gas flow loop. The electromechanical device acts as a pump and effects gas exchange and heat dissipation with a minimum of elements. In other embodiments, electrical discharges cause pressure fluctuations which increase gas circulation without the use of mechanically moved parts. To this end, connecting lines that determine the direction of the flow are placed between the chambers in order to facilitate equalization of gas pressure. A flow circulation loop is thereby created in a quasi-passive manner when suitably constructed.

Abstract: A laser system with a folded beam path is disclosed. The beam path is formed by a plurality of mirrors (18-21). Mirrors (18-21) reflect light in a closed loop from one mirror to the other. Electrodes are disposed on opposite sides of the path between the mirrors and form channels through which the path extends. In addition to serving to direct the beam in a closed loop, one of the mirrors may have the characteristic of reflecting one wavelength of light with a reflectivity of 100% while reflecting other wavelengths of light with a reflectivity of only 85%, such mirror thus acting to pass the other wavelength of light while completely reflecting the one wavelength of light. In one of the disclosed embodiments, four wavelengths of light are directed in a loop comprising mirrors 85% reflective to a wavelength while otherwise 100% reflective which promotes ring laser operations with respect to other wavelengths without passing such other wavelengths.

Abstract: A hybrid laser system, consisting of two different laser units, namely a reference laser (4), possibly an injection laser or a laser amplifier, and a transversely excited laser (TE-laser) (5), possibly a longitudinally pulsed or Q-switched laser, both lasers residing in a common housing. The first laser consists of a tube enclosing an isolated low pressure space and is bathed by coolant. The second laser is a high-pressure space enclosing a folded electrode system (14, 15). In order to achieve uniformity of temperature conditions and wavelength relations, both lasers share a common resonator volume (3) and are in fixed relative adjustment. The reference laser is used as a calibrating laser for frequency tuning of the resonator or, simultaneously, as a local oscillator, whereas the TE laser serves to generate a laser pulse.

Abstract: On one side of a waveguide laser (1), the cavity is terminated by two totally reflecting optical elements or by one totally reflecting element and one (partially) reflecting element (6; 7). The other side of the laser faces the long side (10") of a prism (10), in contact or with spacing, serving to fold the beam. A further prism (11) cooperates with one of the short sides (10') of the prism (10) cooperate to form a variable gap to influence the oscillation of the laser beam. If both of the optical elements (6; 7) are totally reflecting, the beam may be extracted from the cavity at this point. The function of the two prisms is that of a Q-switch with short operating times, which can also be designated as a frustration element.