SU972249A1 - Lamp for irradiation in vacuum ultra-violet region of spectrum - Google Patents

Description

(54) LAMP FOR RADIATION IN VACCUM ULBTR.APIOLET AREA OF SPECTRUM

The invention relates to light sources for the vacuum ultraviolet region of the spectrum and can be applied in spectroscopy, photochemistry, and vacuum technology. Sources emitting molecular continuums of inert gases are known that are excited by microwave generators in discharge tubes with a diameter of 5-12 mm. filled with an inert gas to a pressure of 100-400 tor. 1. The disadvantage of these sources is their small radiating surface, which limits their use as irradiating sources. Closest to the proposed technical solution is a molecular emission lamp containing a glass envelope with an inert gas, a window and electrodes. The molecular continuum in this lamp is obtained by converting resonant photons into photons of molecules. The gas in the cell is resonantly excited and forms molecules that decay, emit a continuum 2. The disadvantage of this device is a small radiating surface (less than 2.5 cm), which does not allow using it as an irradiating source. The purpose of the invention is to increase the radiating surface of the lamp. The goal is achieved by the fact that in the lamp for irradiation in the vacuum ultraviolet (BUF) spectral range containing a glass envelope with an inert gas, a window and exciting electrodes, the envelope is made in the form of a rectangular tube, and the window is located on the side surface of the tube, and electrodes on two mutually opposite walls and equal to them in area. The drawing shows a lamp emitting a molecular continuum of an inert gas excited by a barrier (quiet) discharge. The lamp consists of a glass shell 1, to the side wall of which a window 2 (for example, of magnesium fluoride) is vacuum-tightly attached along its entire length, and external electrodes 3 of metal foil. Electric power is supplied to the electrodes, providing ignition of the barrier (quiet) discharge. The lamp shells are thoroughly degassing at the vacuum post.

filled with an inert gas or a mixture of inert gases to a pressure of 300-700 torr and sealed off.

When a barrier discharge is ignited, the entire cavity of the shell is uniformly filled with a mass of moving tiny sparks directed from one electrode to another. The uniform distribution of sparks ensures the uniform formation of excited inert gas molecules, which, when decomposed, emit a continuous spectrum in the VUV region.

Thus, as a result of the use of a barrier discharge, it is possible to create a gas discharge cavity with a uniform spatial distribution of the electrical energy introduced into the cavity, and consequently, a lamp with a large radiating surface, the value of which reaches 10 cm or more.

In the proposed lamp, the radiating surface is 4-5 times greater than the radiating surfaces of known sources of continuous vacuum ultraviolet radiation, which is especially important when studying the radiation resistance of materials, photochemistry and other studies where uniform irradiance of large surfaces is required. In addition, the proposed lamp is significantly simpler in design compared to the known one, since it does not need to be used.

a resonant lamp and double energy conversion leading to a reduction in the efficiency that occurs in a known lamp.

The lamp can also be used as a translucent source, if the window is attached to the end of the bulb, in this case, the radiation intensity increases by 2-3 times.

Claims (2)

Invention Formula A lamp for irradiation in the vacuum ultraviolet region of the spectrum containing a glass envelope with an interstitial gas, a window and electrodes, characterized in that, in order to increase the radiating surface of the lamp, the glass envelope is made in the form of a rectangular tube, and the window is located on the side the surfaces of the tube, and the electrodes are perpendicular to the window on two mutually opposite walls and are equal in area to them. Sources of information taken into account in the examination 1. A. Seidel, E. Schrader, Vacuum, spectroscopy and its application, “Science, 1976, p. 20-32. 2. US patent No. 4075505, cl. H 02 M 5/04, published 1978