RU2264604C2 - Emission source for spectrophotometer - Google Patents

Abstract

FIELD: spectrophotometry.

SUBSTANCE: device has halogen lamp and second emitter, both mounted on same optical axis, while second emitter is made in form of transparent electrode-less gas-metal fill lamp with high-frequency inductor, both emitters and inductor are positioned coaxially in such a way, that halogen lamp is mounted beyond grounded end of inductor, and electrode-less lamp is mounted in maximum of high-frequency electromagnetic field of inductor before its ungrounded end. Electrode-less lamp can be made in form of quartz reservoir, containing xenon Xe, mercury Hg, cadmium Cd, and zinc Zn.

EFFECT: expanded working spectrum range, higher sensitivity, higher precision.

2 cl, 1 tbl, 3 dwg

Description

The invention relates to devices used in spectrophotometers as an emitter in the spectral region from 202 nm to 3500 nm, which allows to obtain an intense radiation spectrum after a monochromator spectrophotometer. The invention will find application in science and technology using spectrophotometric devices, for example: in medicine, in factory laboratories in various industries, with environmental control of wastewater, etc.

Currently, in spectrophotometers to expand the spectral range from 190 nm to 1100 nm, as a rule, two replaceable emitters are used. A DDS-30 type deuterium emitter is used on the spectral range from 190 nm to 400 nm, and an incandescent lamp in a glass or quartz balloon is used on the spectral range from 400 nm to 1100 nm, while the emitters are rearranged either manually during operation on the spectrophotometer, or in automatic mode, depending on the design of the spectrophotometer.

Known fast emitter on an electric arc mercury-xenon constant current lamp type C6987 of the Japanese company "Hamamatsu" [1] with a spectral range of radiation from 185 nm to 2000 nm. The disadvantage of this emitter is its high commercial cost (about $ 600 without a power source), so its use in simplified design spectrophotometers specialized for laboratory routine analyzes is unprofitable due to its high cost.

Known combined emitter DNM-15 [2], GOI, St. Petersburg, built on a deuterium lamp that emits in the UV range, and a tungsten filament, which is the source of the visible region of the spectrum, is mounted in the lamp balloon. The radiation from the filament passes through the hole in the anode electrode of the deuterium lamp, as a result of which the spectral range of the lamp extends to the near infrared region, up to 2000 nm. The disadvantage of this emitter is the low aperture due to the small aperture and weak radiation from the filament.

The closest known one is a Hamamatsu combo emitter (prototype) [3], also built on a deuterium lamp of this company L2D2 and a halogen lamp according to the circuit depicted in Fig. 1.

The emitter is a compact system consisting of a halogen lamp 1, a focusing lens 2 and a deuterium lamp 3 mounted along the optical axis. The deuterium lamp 3 has a through hole 4, the anode with a hole 5 in the screen electrode 6. The radiation of the halogen lamp 1, focused by a lens 2 into the through window 4 of the screen electrode 6 and the hole in the anode 5 of the deuterium lamp 3, located along the optical axis with an exit outlet UV radiation from deuterium plasma passes through the emitting plasma of deuterium lamp 3. Thus, the total radiation from both lamps falls into the input collimator of a spectrophotometer monochromator, followed by a sweep of the spectrum over the operating range.

The disadvantages of this combined emitter is also a low aperture due to the small aperture in the visible and in the UV regions of the spectrum and its high cost. An increase in aperture entails a significant decrease in the service life of a deuterium lamp due to the departure of deuterium ions from its volume.

The objective of the present invention is to increase the luminosity of the radiation source and, as a result, expand the working spectral range, increase the sensitivity and accuracy of spectrophotometric analysis while reducing its cost.

The problem is solved due to the fact that the proposed radiation source for spectrophotometers consists of two emitters mounted on the same optical axis, one of which is a halogen incandescent lamp, and the second emitter is made in the form of a transparent electrodeless gas-vapor-filled lamp (in operating mode) with a high-frequency inducer. The electrodeless lamp is made in the form of a quartz balloon. In this case, both emitters and the inductor are aligned so that the halogen lamp is installed behind the grounded (cold) end of the inductor, and the transparent electrodeless lamp is in front of the ungrounded (hot) end of the inductor at the maximum of the high-frequency electromagnetic field of the inductor. A quartz cylinder of an electrodeless lamp contains a small amount of xenon (Xe), mercury (Hg), cadmium (Cd) and zinc (Zn) in its volume. An electrodeless lamp can be placed in a glass bottle. The proposed design of the radiation source provides free passage of radiation from a halogen lamp through an inductor and a transparent cylinder of an electrodeless lamp with a radiating gas-vapor plasma in the operating mode.

The claimed fast combined emitter is much cheaper (no more than $ 30), and its use in spectrophotometers for routine analyzes significantly expands their working spectral range, increases the sensitivity and accuracy of spectrophotometric analyzes due to the high aperture of the emitter and practically does not affect their price. In addition, the use of the proposed radiation source in spectrophotometers of this type will allow analytical spectrophotometry of industrial products with increased background absorption, for example, petrochemical products.

Figure 2 shows a General view and an optical diagram of the proposed radiation source for a spectrophotometer.

Figure 3 shows the emission spectra of the proposed emitter on a halogen incandescent lamp with an electrodeless lamp (Hg + Cd + Zn) - 1 and on a halogen incandescent lamp without a second electrodeless lamp - 2.

The radiation source (figure 2) consists of a halogen incandescent lamp 1 in a quartz cylinder, a high-frequency inductor 2 and a transparent electrodeless lamp 3 of mercury-cadmium-zinc (Hg + Cd + Zn) filling or a combination of any pair that is a quartz cylinder, the initial the pressure in which is about 1 mm Hg due to the addition of argon (Ar) or xenon (Xe) during their manufacture. In the working (discharge) state, the pressure inside the cylinder can reach about 2 atm. The system of these elements is placed in the electrostatic screen 4.

An electrodeless lamp 3 is installed in front of the "hot" (non-grounded) end of inductor 2. Its fastening has three degrees of movement within 2 ÷ 3 mm indicated by "orts" on its mounting element 5: up-down, right-left and forward-backward, which ensures accurate installation of an electrodeless lamp in the “antinode” of the high-frequency electric component of the electromagnetic field of a solid serial circuit of a high-frequency generator, composed of inductor elements and one or two series-connected air capacitors s C (not shown in the figure). Behind the "cold" (grounded) end of the inductor 2, a halogen incandescent lamp 1 is installed in the installation element 6, also with the corresponding installation movements marked with "orts". In this case, the electrodeless lamp has a focusing effect, which eliminates the need for introducing a collimating lens into the circuit.

All of these elements are located on the same optical axis, so that radiation from a halogen lamp freely passes through the internal space of the high-frequency inductor 2 and a quartz cylinder of an electrodeless lamp 3, which contains an emitting gas-vapor plasma in the operating mode.

In the idle mode (at ambient temperature) in the volume of the electrodeless lamp in the gas state are only xenon (Xe) and a small amount of mercury vapor (Hg) at a total pressure of 1 mm Hg, which should provoke the initial high-frequency discharge, with cadmium (Cd) and zinc (Zn) are in the solid state, and mercury (Hg) in the liquid state.

In the operating mode, gas-vapor plasma is contained in the volume of the electrodeless lamp at a temperature of more than 200 ° C, excited by the high-frequency field of the inductor and emitting spectral characteristic lines of the elements incorporated in the flask: mercury (Hg), cadmium (Cd) and zinc (Zn).

The proposed radiation source works as follows. A halogen incandescent lamp 1 of any type in a quartz canister, mounted behind the grounded end of the high-frequency inductor 2, emits a continuous spectrum in the range from 330 nm to 3500 nm. An electrodeless lamp 3 installed in front of the non-grounded end of the inductor absorbs high-frequency energy (of the order of 10 watts), as a result of which a discharge lights up inside the electrodeless cylinder, the temperature and pressure sharply increase, and the high-frequency plasma emits a set of spectral lines in the UV region from 202 nm to 600 nm (depending on the filling of the electrodeless balloon). Both emitting elements of the combined radiation source are mounted on the optical axis in such a way that the radiation from the halogen lamp 1 passes through the inductor 2 and the quartz cartridge with the luminous plasma of the electrodeless lamp 3. With this installation, the total radiation from both emitting elements of the combined radiation source provides an intensive spectrum over the entire range from 200 nm to 3500 nm and can be sent to the input collimator of a spectrophotometer monochromator.

The table lists the spectral lines of radiation in the UV region of the spectrum when filling an electrodeless lamp Zn, Cd and Hg.

Table Element The degree of ionization. And λ, nm Excited energy., EV The degree of ionization. And λ, nm Excited energy., EV Zn II 202.6 6.12 I 307.6 4.03 II 206.2 6.01 I 328.2 7.78 I 213.9 5.8 I 330.3 7.78 I 250.2 10.98 I 334.5 7.78 I 255.8 8.83 Cd II 214.4
I 226.5 5.78
5.47 I 326.1
I 328.2 3.8
7.78 I 228.8 5.41 I 361.0 7.37 Hg I 253.6 4.88 I 365.5 8.85 I 297.0 8.85 I 404.5 7.51 ÷ 7.92 I 313.2 8.85 I 435.7 7.73 I 334.3 9.2 I 546.1 7.73 I 578.2 9.8

The spectral composition of the radiation of an electrodeless lamp is represented by a set of bright characteristic lines of these elements concentrated in the wavelength range from 200 nm to 600 nm with a threshold emission of a continuous spectrum of a halogen lamp from a wavelength of 330 nm to 3500 nm.

The full spectral characteristic of a combined emitter composed of an electrodeless filling emitter (Hg + Cd + Zn) and a KGM12-10 halogen incandescent lamp is shown in FIG. 3.

As follows from the table and figure 3, the UV region of the spectrum of the combined emitter is quite densely filled with bright narrow characteristic spectral lines of mercury, cadmium and zinc. The distribution density of these lines is quite sufficient for spectrophotometers of a simplified design, providing a routine quantitative analysis of the production of organic and inorganic products. The analyzed impurities in terms of selective spectral absorption in the UV region of the spectrum are always represented by absorption bands of the order of 20 nm, which is sufficient to overlap several narrow characteristic spectral lines of radiation of these elements shown in the table.

This is also clearly seen in figure 3, which shows the relative brightness of the emission lines in the UV region of the spectrum, which is 2-3 times higher than the brightness of a halogen lamp in its visible short-wavelength region of the spectrum.

Sources of information

1. Flyer for Hamamatsu, Photonic devices for scintific instruments, 2000. p. 20.

2. Technical description DNM-15, State Optical Institute, St. Petersburg, 2000

3. Advertising brochure of the company "Hamamatsu," Photonic devices for scintific instruments, 2000. p. 18 (prototype).

Claims (2)

1. The radiation source for the spectrophotometer, including a halogen incandescent lamp and a second emitter mounted on the same optical axis, characterized in that the second emitter is an electrodeless lamp with a high-frequency inductor, made in the form of a gas-filled quartz cylinder, while both emitters are aligned so that that the halogen lamp is installed behind the grounded end of the high-frequency inductor, and the electrodeless lamp is located at the antinode of the high-frequency electric component of the electric the magnetic field of a solid serial circuit of a high-frequency generator, composed of a high-frequency inductor and two air capacitors connected in series with it, in front of the ungrounded end of the high-frequency inductor. 2. The radiation source for the spectrophotometer according to claim 1, characterized in that the electrodeless lamp contains xenon, mercury, cadmium and zinc (Xe + Hg + Cd + Zn) or a combination of metals with xenon and mercury, for example ( Xe + Hg + Cd) or (Xe + Hg + Zn).

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