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Description  |
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FIELD OF THE INVENTION
The invention relates generally to spectroscopy and more specifically the
pre-concentration of a sample substance in the flow injection analysis.
BACKGROUND OF THE INVENTION
An arrangement for the pre-concentration of a sample substance for
spectroscopical purposes in the flow injection analysis is known from a
paper by Olsen et al in the journal "The Analyst", vol 108, 905-917. Into
parallel peristaltic conduits, a peristaltic pump feeds water, a buffer
liquid in the form of ammonium acetate and an eluting liquid in the form
of nitric acid. An injection valve is arranged in the hose conduit, into
which water is fed. The injection valve contains a through-passage and a
sample loop, which is adapted to be optionally switched into the flow in
the hose conduit. Then the through-passage is switched into the hose
conduit, a flow of sample liquid is passed through the sample loop, such
that the sample loop is filled with sample liquid. After the injection
valve has been changed over, the sample loop filled with sample liquid is
connected to the hose conduit carrying the water flow, such that the
sample liquid is taken along by the water flow. The water and the sample
liquid, respectively, are mixed with the buffer liquid and, in a first
valve position of a valve arrangement, flow through an ion-exchanger
column from a first end of the ion-exchanger column to a second end. The
second end communicates with a waste outlet. In the first valve position
of the valve arrangement the eluting fluid flows to a nebulizer and is
sprayed into the flame of an atomic absorption spectrometer. Now
pre-concentration of the sample takes place in the ion-exchanger column.
The valve arrangement is subsequently changed over to a second valve
position. In this second valve position, the water and ammonium acetate
hose conduits communicate with the waste outlet. The second end of the
ion-exchanger column communicates with the hose conduit carrying the
eluting liquid. The first end of the ion-exchanger column communicates
with the nebulizer of the atomic absorption spectrometer. The eluting
liquid flows through the ion-exchanger column in a direction opposite to
the previous direction and elutes the pre-concentrated elements to be
determined in to the nebulizer and thus into the burner of the atomic
absorption spectrometer.
From a paper by Hartenstein et al in "Analytical Chemistry" 57 (1985),
21,25 and a paper by Zhaolun Fang et al in "Analytica Chimica Acta" 200
(1987), 35-49, an arrangement is known wherein a first sample liquid with
an associated buffer liquid and a second sample liquid with an associated
buffer liquid are fed by a first peristaltic pump. The sample liquids are
mixed with the associated buffer liquids in tube coils, which are
connected downstream to the peristaltic pump. The thus obtained sample and
buffer liquids are passed to a first valve. In a first valve position of
the first valve the sample and buffer liquids are passed to a first end of
an associated ion-exchanger column. The other second ends of the
ion-exchanger columns each communicate with a waste outlet. Then the two
ion-exchanger columns are loaded in a parallel with the sample liquid, the
sample is pre-concentrated in the columns. A second peristaltic pump feeds
an eluting liquid and water. In a first position of the valve the water is
passed to the nebulizer of a plasma burner. In this first position of the
valve the eluting liquid communicates with a waste outlet. In the second
position the valve passes the eluting liquid to the second end of one of
the ion-exchanger columns, the first end of which then communicates with
the nebulizer. The ion-exchanger column exposed to the eluting liquid is
selected by a change-over valve.
By the use of two ion-exchanger columns, which are loaded in parallel, the
analysis time can be approximately halved. Instead of the eluting liquid,
water is passed to the nebulizer while the ion-exchanger columns are
loaded. The water washes the nebulizer and stabilizes the plasma.
In all known arrangements of the present type the ion-exchanger columns
have substantially constant cross section over their entire length. The
ion-exchanger columns according to the paper by Zhaolun Fang et al in
"Analytica Chimica Act" 200 (2987), 35-49 have conically tapered ends.
This is to ensure uniform flow. However, the essential portion of the
ion-exchanger column, in which the sample is pre-concentrated, is
cylindrical.
In order to obtain a high pre-concentration of the sample in the
ion-exchanger column, a relatively long pre-concentration time is required
with the known arrangements. This results in dead times of the
spectrometer and to inadmissibly high consumption of inert gas when a
plasma burner is used. Reduction of the analysis frequency results in
difficulties with the calibration in routine applications. Increased
drifts of the experimental conditions occur namely due to the increase
time of the experiment. The drifts have to be taken into account by more
frequency calibration actions. This, however, further reduces the
efficiency of the method. A further problem therein is the dispersion of
the eluted sample slug, which counteracts an increase in the degree of
sensitivity and thus makes longer pre-concentration times necessary.
SUMMARY OF THE INVENTION
The present invention is directed to an ion-exchanger column for use in
spectroscopy. In accordance with the present invention, the ion-exchanger
column is tapered from the second end toward the first end.
The use of such a shape of the ion-exchanger column means that, when the
ion-exchanger column is loaded, which is effected from the narrow first
end of the ion-exchanger column, the sample is pre-concentrated in the
area of this narrow first end, i.e., in the "tip" of the ion-exchanger
column in an area of reduced diameter. From this area the sample is then
eluted in very short time by the eluting fluid. Therefore, a sample slug
of high concentration but short duration emerges from the ion-exchanger
column. Correspondingly, the spectrometer supplies a high but very short
output impulse. Thereby, a high degree of sensitivity can be achieved,
which is determined by the height of the impulse, without the
pre-concentrated sample quality, which is an analog to the area of the
impulse, having to be large and thus the time of pre-concentration having
to be undesirable long. It has been shown that, with an ion-exchanger
column according to the invention, at high analysis frequency a
sensitivity can be achieved which is high compared to the prior art.
Therefore, it is an object of the invention to increase the degree of
sensitivity of the measurement in spectroscopical analysis without the
time for a single analysis becoming impermissibly high.
It is a further object of the invention to counteract the dispersion of the
eluted sample slug in the pre-concentration of a sample substance for
spectroscopical reasons in the flow injection analysis.
These and other objects will become more readily apparent in view of the
following more detailed description.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows a circuit diagram of an arrangement for the pre-concentration
of a sample for spectroscopical purposes by means of an ion-exchanger
column in flow injection analysis in the mode of operation
"pre-concentration"
FIG. 2 shows a portion of the arrangement of FIG. 1 in the mode of
operation "measurement".
FIG. 3 illustrates the time sequence of a measurement cycle with the
arrangement of FIGS. 1 and 2.
FIG. 4 shows a longitudinal section of an ionexchanger column in the
arrangement of FIG. 1.
FIG. 5 shows the signals, which were obtained with repeated measurements
with an arrangement according to FIG. 1.
PREFERRED EMBODIMENT OF THE INVENTION
In FIG. 1 numeral 10 designates a first peristaltic pump. The peristaltic
pump 10 feeds a sample liquid, which is supplied through a port 12 and a
hose conduit 14. Furthermore, the peristaltic pump 10 feeds a buffer
solution, which is supplied through a port 16 and a hose conduit 18. The
two hose conduits 14 and 18 are united in a branching point 20. a common
conduit 22 leads from the branching point 20 to a valve 24.
A second peristaltic pump 26 feeds an eluting liquid, e.g., 2-molar
hydrochloric acid. The eluting liquid is supplied through a port 28 and a
hose conduit 30. the hose conduit 30 likewise communicates with the valve
24.
Furthermore, a conduit 32 communicates with the valve 24, through which
conduit 32 de-ionized water is supplied.
A port 34 of the valve 24 communicates with the nebulizer of a burner 36 of
an atomic absorption spectrometer, which is only schematically illustrated
in FIG. 1. A further port 38 of the valve communicates with a waste outlet
40. A port 42 of the valve 24 likewise communicates with waste outlet 40.
A port 44 of the valve 24 communicates with a first end 46 of an
ion-exchanger column 48. A port 50 of the valve 24 communicates with a
second end 52 of the ion-exchanger column 48. The second end 52 has a
larger diameter than the first and 46.
In the first valve position of the valve 24 illustrated in FIG. 1, the
common conduit 22 communicates with the first end 46 of the ion-exchanger
column 48 through the valve 24 and its port 44. The second end 52 of the
ion-exchanger column 48 communicates with the waste outlet 40 through the
port 50 of the valve 24, the valve 24 and the port 38. The first pump 10
is switched-on (FIG. 3) and the second pump 26 stands still. Thus, no
eluting liquid is fed. De-ionized water is supplied to the nebulizer of
the burner 36 through conduit 32, the valve 24 and port 34. In this way
the nebulizer is rinsed.
In this first valve position corresponding to the mode of operation
"pre-concentration", sample and buffer liquid flow from the first end 46
to the second end 52 through the ion-exchanger column 48. Thereby the
elements to be determined are retained and pre-concentrated in the
ion-exchanger column.
After a period of time of 20 seconds, for example, (FIG. 3) the second pump
26 is switched on. At the same time the valve 24 is changed over into its
second valve position. In the second valve position of the valve 24, which
is illustrated in FIG. 2, the conduit 22 communicates with the waste
outlet 40 through the valve 24 and port 42. Then the peristaltic pump 10
aspirates a new sample and thus displaces the previous one with the
elements to be determined and pre-concentrated in the ion-exchanger column
from the conduit 22 and the valve 24. The second pump 26 feeds eluting
liquid through the peristaltic conduit 30, the valve 24 and port 50 to the
first end 52 of the ion-exchanger column 48. The second end of the
ion-exchanger column 48 communicates with the nebulizer of the burner 36
through the valve 24 and port 22. Thus, the second pump 26 urges eluting
liquid from the second end 52 through the ion-exchanger column 48 to the
first end 46. Therewith, the elements to be determined and
pre-concentrated in the ion-exchanger column are eluted. The elutant is
transported into the nebulizer of the burner 36 by the eluting liquid.
Therewith, the ion-exchanger column 48 has the function of the usual
sample loop in the flow injection analysis. However, the ion-exchanger
column 48 also effects a pre-concentration of the sample.
The ion-exchanger column 48 is tapered from the second end 52 toward the
first end 46, which is schematically shown in FIG. 1 and illustrated in
detail in FIG. 4. In the illustrated preferred embodiment the
ion-exchanger column 48 comprises a conical funnel 54. This funnel 54 is a
conventional Eppendorf-pipette tip of plastic, which is cut-off at its
pointed first end 46, such that an outlet having an inside diameter of
approximately 0.5 mm is obtained. This funnel 54 is densely packed with a
granular ion-exchanger 56. The ion-exchanger is 8-quinolinol
azoimmobilized on porous glass having a defined pore width with a particle
size of 125 -177 .mu.m and a pore diameter of 500 nm. Such an ionexchanger
is delivered by Pierce Chemical Company under the marking CPG/8-Q. The
funnel shape of the ion-exchanger column allows the ion-exchanger 56 to be
packed very densely. The ion-exchanger 56 is held together by glass wool
58 from the second end 52.
The valve 26 communicates with the nebulizer through the shortest length
possible of PTFE-conduit 60. The PTFE-conduit 60 has a length of 5 cm and
an internal diameter of 0.5 mm.
As can be seen from FIG. 3, the device is programmed for a
pre-concentration time of 20 seconds and an eluting time of 10 seconds.
Thus, this results in 120 analyses per hour. The flow rate of the sample
liquid for the pre-concentration is 4.8 ml/minute. The buffer liquid is an
ammonium acetate solution having a pH-value of 9. The buffer liquid is
supplied with a flow rate of 0.2 ml/minute. It is mixed in the branching
point 20 with the acid sample liquid having a pH-value of 3. A value of
2.7 ml/minute has turned out to be optimal as the flow rate of the eluting
liquid, degassed 2-molar hydrochloric acid. The elutant is supplied to a
nebulizer with an aspiration rate of 10 ml/minute.
FIG. 5 shows signals, which were obtained with repeated measurements of the
same sample liquid with an arrangement according to FIGS. 1 to 3. The
sample liquid was a copper solution having a concentration of 100 .mu.g/1
Cu. A pre-concentration took place with an ion-exchanger column of the
type illustrated above having a volume of 65 .mu.l. The sample volume was
1.6 ml. The analysis frequency was 120 measurements per hour. The
pre-concentration factor was 25. This resulted in a mean deviation (RSD)
of 1.2% of the measurements.
The described arrangement is a system which bridges the large sensitivity
gap of 2-3 magnitudes between the flame-ASS and the atomic absorption
spectroscopy with a graphite furnace. A 20-30-fold signal increase results
relative to the usual flame-AAS with similar analysis frequency and the
same sample consumption.
The spectroscopical analytical instrument can be an atomic absorption
spectrometer, the eluate being sprayed from the ion-exchanger column into
a flame. The flame is arranged in the path of rays of a measuring light
beam of the atomic absorption spectrometer. The analytical instrument can
also be an atomic absorption spectrometer operating with electrothermal
atomization. Finally, the spectroscopical analytical instrument can be an
atomic emission spectrometer having a plasma burner. In such an atomic
emission spectrometer, a plasma of high temperature is generated in an
inert gas flow by a high frequency field. A sample liquid is aspirated
into this plasma. The sample liquid is atomized in the plasma. The atoms
are stimulated to emission of radiation. Thereby, by means of a
polychromator, a plurality of elements can simultaneously be determined in
the sample. By pre-concentration of elements to be determined in the
ion-exchanger column and subsequently supplying the eluate to the
analytical instrument, the sensitivity of the measurement is increased.
Although the preferred embodiment has been illustrated and described, it
will be obvious to those skilled in the art that various modifications may
be made without departing from the spirit and scope of this invention.
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