CZ302756B6 - Modular structure of hydride atomizers for atomic absorption spectrometry - Google Patents

Abstract

In the present invention, there is disclosed a hydride atomization apparatus for atomic absorption spectrometry for determining elements forming volatile compounds. The apparatus according to the present invention employs a modular atomizer structure in the form of L letter. Horizontal arm of the atomizer consists of two concentric tubes (1, 2), en inner tube and an outer tube, coupled and sealed at their both ends by Teflon intermediate rings (3), only. The inner optical tube (1) is thus easily replaceable and can be made of arbitrary suitable material. A quartz window (5) is inserted on said inner optical tube (1) supply end where is the outlet of a tube (6) serving for the supply of hydride into the atomizer.

Description

Technical field

The present invention relates to a new design of a device for atomization of volatile compounds for atomic absorption spectrometry (AAS) for the determination of volatile compound-forming elements by the AAS method.

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BACKGROUND OF THE INVENTION

Elements forming analytically useful volatile compounds are determined by the AAS method such that the determined element is converted by chemical reaction to the corresponding volatile compound, which is expelled from the reaction mixture and fed to an atomizer located in the optical axis of the atomic absorption spectrometer. The best-known analytically useful volatile compounds are the hydrides As, Sb, Se, Sn, Pb, Te, Bi, and Ge, and ethyl derivatives of Sn, Pb, Hg, Cd and Se. A heated atomizer usually made of quartz is usually used to atomize the volatile compounds. A conventional heated quartz atomizer consists of a feed arm and an optical tube whose axis is identical to the optical axis of the spectrometer. The optical tube is 10 to 20 cm long and a substantial part is heated from the outside to a temperature of 700 to 1100 ° C. The feed arm is a tube fused to the optical tube usually at a right angle in the center thereof. The atomizer is then in the form of a T-tube, whose feed arm serves to supply the volatile compound carried by the carrier gas stream to the horizontally positioned optical tube. Quartz windows may be located at both ends of the optical tube; then side outlets are fused before the end of the optical tube to allow the gases to exit the optical tube. Some quartz atomizers do not have the shape of a T-tube (described above) but an L-tube. In these atomizers, the feed arm is not fused in the center of the optical tube but near one end of the horizontal optical tube. The optical tube is then provided with a quartz window at the end of the optical tube that is near the feed arm. The currently used conventional quartz atomizers are described in detail in a monograph [J. Dedina and D. L. Tsalev, Hydride Generation Atomic Absorption Spectrometry, Wiley, Chichester, 1995] and references therein. A common feature of conventional heated quartz atomizers is that the optical tube has, at least in substantial part, a simple wall (without cavities). Another common feature is that the feed arm and the optical tube are always (in the case of both T- and L-tubes) made of one piece, usually fused together.

Conventional heated quartz atomizers suffer from severe inherent deficiencies, namely very low resistance to atomization interference and insufficient linearity of analytical calibrations. These deficiencies are largely overcome by the new V40 atomizer [J. Dědina, T. Matoušek, A method for atomizing volatile compounds for atomic absorption spectrometry, and apparatus for carrying out the method, patent No. 287635], the principle of which is to provide a controlled amount of oxygen into the optical tube of a heated miniature atomizer. The atomizer may be in the form of a T-tube where the feed arm is fused to the optical tube at its center at right angles, but also the L-tube where the feed arm is fused near one end of the horizontal optical tube. In the case of an L-arrangement, the optical tube must be provided with a quartz window at the end which is near the feed arm.

The only construction described in the literature so far in the multiatomizer [J. Dedina and T. Matousek,

Multiple microflame - a new approach to hydride atomization for atomic absorption spectrometry, J. Anal. At. Spectrom. 15 (2000) 301 to 304 and T. Matoušek, J. Dědina, A. Selecká, Multiple microflame quartz tube atomizer - further development towards the ideal hydride atomizer for atomic absorption spectrometry Spectrochim. Acta B 57 (2002) 451 to 462] is based on an optical tube consisting of two quartz concentric tubes, an inner and an outer tube, wherein the inner concentric tube is punctured by evenly spaced seven pairs of opposing holes having a diameter of about 0, 5 mm. The openings were made by the glassmaker manually - by melting. This technique does not allow smaller holes to be made. A mixture of oxygen and inert gas is introduced into the cavity between the two concentric tubes. The atomizer has the shape of a T-tube where the feed arm is fused to the optical tube at its center at right angles.

The use of this multiatomizer largely eliminates the disadvantages of conventional heated quartz atomizers. While maintaining excellent sensitivity, the resistance to atomization interference was greatly improved and the linearity of the analytical calibrations significantly improved. For example, as reported in the above-cited publications, the resistance to atomization interference to arsenic interference in the selenium assay increased by at least one order, and the linear dynamic range of the selenium calibration dependence was expanded to 20-fold higher concentrations.

Despite the improved performance of the multiatomizer described (as compared to conventional heated quartz atomizers), the resistance to atomization interference and sensitivity still do not reach the parameters expected with the ideal operation of the multiatomizer. Recent unpublished experiments conducted in the authors' laboratory have shown that the observed unideality is due to an uneven oxygen supply along the length of the optical tube. A uniform supply of oxygen can be achieved either by substantially increasing the number of holes in the quartz optical tube at the same time as significantly reducing their size, or by using an optical tube made of a porous material. However, this material must be chemically inert and resistant to high temperatures. Only porous quartz glass or AUCh-based ceramics are therefore suitable.

A major obstacle to making the analogy of the above described multiatomizer from a multi-apertured quartz tube, a porous quartz tube and a ceramic tube is the impossibility of connecting the feed arm to these optical tubes in the middle of their length. The high temperature required to melt the feed arm to the quartz glass led to sintering of holes or pores. Ceramics cannot be melted to quartz glass at all. The same argument applies to the impossibility of making an L-tube multiatomizer where the feed arm is fused near one end of the optical tube.

SUMMARY OF THE INVENTION

The problem of the impossibility of making a multiatomizer from a multi-apertured quartz tube or a suitable porous material is solved by the modular design of an L-shaped atomizer, consisting in that the horizontal arm of the atomizer consists of two concentric tubes, inner and outer, connected and sealed both ends only with Teflon between rings. The inner tube, hereinafter also referred to as an optical tube, is therefore easily replaceable and can be made of any suitable material. One of its inlet ends is fitted with a Teflon adapter quartz window. A tube serving to feed the hydride to the atomizer also opens into the Teflon extension. The outer concentric tube is made of quartz glass and is provided with one or more inlets for supplying a mixture of oxygen and inert gas. The length of the horizontal arm of the atomizer is chosen so that it can be heated by a standard electric furnace to temperatures up to 1100 ° C and that the temperature at its ends where the Teflon between rings and the Teflon attachment with quartz window is not exceeded 300 ° C temperature at which Teflon is still stable, i. ranging from 150 to 200 mm.

The advantage of this device is, compared to a complicated T-multiatomizer having identical analytical parameters, the simplicity and flexibility of easy replacement of the optical tube while maintaining the other parts of the atomizer. Another major advantage of this modular arrangement is that it enables the use of new types of optical tubes (multiple perforated quartz tubes, porous quartz tubes and ceramic tubes), which, in contrast to existing hydride atomizer configurations, promise a significant improvement over existing hydride atomizer types. .

Overview of the figure in the drawing

An example of the device according to the invention is illustrated in more detail by means of the figure in which the device according to the invention is shown schematically.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An example of a device according to the invention is illustrated in greater detail by means of an illustration in which the device according to the invention is schematically illustrated.

The horizontal arm of the atomizer is illuminated more closely from two concentric tubes, the inner, the so-called optical tube I, and the outer tube 2, connected and sealed at both ends by Teflon intermediate rings 3. The concentric tube axis is identical to the optical axis of the spectrometer. The replaceable optical tube 1 has a length of 160 mm. On the left end of the optical tube is mounted a Teflon extension 4 with a quartz window 5 and a Teflon feed arm 6. The optical tube 1 used in this example of the device according to the invention (inner diameter 6 mm, wall thickness 1 mm) has at its periphery 128 uniformly spaced holes of 0.5 mm diameter. Between the two concentric tubes 1, 2 is a cavity 7 into which the inlets 8 run. The outer concentric tube 2 is made of quartz glass. It has a length of 165 mm, an inner diameter of 15 mm, a wall thickness of 1.5 mm and three arms 8 are welded to it. All connections are sealed with Teflon tape. Atomizer parts made of Teflon are hatched in the figure.

Function of the device: Atomizer is heated from outside to 700 to 1000 ° C by means of a resistance oven. The feed arm 6 of the optical tube 1 is fed with the hydride of the element to be measured in a stream of carrier gas (usually argon) mixed with hydrogen. Oxygen, whose uniform access to the inside of the optical tube is necessary for the optimum functioning of the atomizer, is fed into the cavity 4 between the two concentric tubes 1, 2 by inlets 8 in the outer concentric tube 2 and from there flows through the holes in the optical tube 1.

In preliminary experiments, the functionality of the device according to the invention was tested to determine selenium as a model for hydride forming elements (see drawing). It was found that all tested analytical parameters (linearity of calibration functions, sensitivity, repeatability)

The L-design of the multiatomizer is at the same level as the existing T-set multiatomizer. This result is very useful for analytical practice as it makes it possible to replace a complicated T-multiatomizer with a much simpler and more flexible L-design.

Industrial applicability

The device according to the invention, the modular design of the hydride atomizer, can be used for the AAS to determine analytically useful volatile compound-forming elements, in particular hydrides of As, Sb, Se, Sn, Pb, Te, Bi and Ge ethyl derivatives of Sn, Pb, Cd and Se. sample types, eg clinical, food, environmental and industrial.

Claims (4)

PATENT CLAIMS Modular design of a hydride atomization device for atomic absorption spectrometry, characterized in that the horizontal arm of the atomizer with a length of 150 to 200 mm consists of two concentric tubes, preferably of quartz glass, an inner optical tube (1), and an outer Tubes (2), provided with at least one inlet (8) for supplying a mixture of oxygen and inert gas, which are connected and sealed at both ends by Teflon intermediate rings (3), with one Teflon extension (4) at one end of the inner optical tube (1). a quartz window (5) is fitted and a Teflon feed arm (6) opens into the Teflon extension (4) for feeding the hydride to the atomizer. The modular structure of the hydride atomization device according to claim 1, characterized in that the inner optical tube (1) is made of multiple perforated quartz glass. Modular design of the hydride atomization device according to claim 1, characterized in that the inner optical tube (1) is made of porous quartz glass. The modular structure of the hydride cathodization device according to claim 1, characterized in that the inner optical tube (I) is made of a porous ceramic material.