Metrohm 828 IC Dual Suppressor User Manual

1.2 How it works

828 IC Dual Suppressor/ 8.828.1003 Instructions for Use

3

The counter ions (Na

+

) of the eluent are exchanged for the hydrogen

ions (H

+

) of the resin in the cell. If NaOH is used as the eluent then

water will be formed; if NaHCO

3

/Na

2

CO

3

is used as the eluent then

carbon dioxide is produced. At the same time the counter ions of the

sample (M

+

= metal cation) are exchanged for protons from the resin.

Together with the sample anions these form acids which have an

increased conductivity, e.g. hydrochloric acid, nitric acid, etc. This

provides an improved signal-to-noise ratio and an improved detection

sensitivity.

2. During the operation of the 828 IC Dual Suppressor a direct current

is constantly applied to the suppressor cell electrodes.

Water in the cell is electrolyzed and the following electrode

reactions take place:

Anode:

2 H

2

O š 4 H

+

+ O

2

(g) + 4 e

-

Cathode: 2

H

2

O + 2 e

-

š 2 OH

-

+ H

2

(g)

At the anode hydrogen ions and gaseous oxygen are produced; at

the cathode hydroxide ions and gaseous hydrogen. In this way the

hydrogen ions produced at the anode continuously regenerate the

cation exchanger. The sodium cations of the eluent and the cations

of the sample wander toward the cathode in the direct current field.

The eluate that leaves the suppressor cell on the cathode side

contains the hydroxide salts of these cations, gaseous hydrogen

and some sample anions (in the form of their sodium salts). The

eluate at the anode side contains carbonic acid or water together

with gaseous oxygen and some sample ions (protonated form). The

protonated sample anions are eluted toward the detector with

carbonic acid or water.

3. After leaving the suppressor cell all eluates pass through a

degassing unit. Oxygen and hydrogen are removed from the eluate

flows at the anode and cathode sides respectively before they

reach the waste container. The eluate at the OUT connection (see

Figure 1, Figure 10) contains the sample anions and carbonic acid

(if a carbonate/bicarbonate eluent is used) and passes the

degassing unit before reaching the conductivity detector. In the

degassing unit the carbonic acid dissociates to form carbon dioxide

and water. Carbon dioxide is removed and water remains.

This further reduces the background conductivity of the eluate to

provide improved sensitivity and a more stable baseline. This

means that it is possible to use carbonate/bicarbonate gradients.

The injection peak (water dip), which is often overlapped by quickly

eluting anions, and the system peak, which interferes with the

detection of anions which coelute with it, are eliminated.