J.Natn.Sci.Foundation Sri Lanka 2008 36 (I): 25-31 

R E S E A R C H A R T I C L E 

Linear sweep voltammetric determination of free chlorine in waters 
using graphite working electrodes 
K.A.S. Pathiratne*, S.S. Skandaraja and E.M.C.M. Jayasena 
Department of Chemistry* Faculty of Science, University of Kelaniya, Kelaniya. 

Revised: 16 June 2007 ; Accepted: 23 July 2007 

Abstract: Applicability of linear sweep voltammetry using 
graphite working electrodes for determination of free chlorine in 
waters was demonstrated. Influence of the nature of supporting 
electrolyte, its concentrations, pH and rate of potential variation 
of working electrode on voltammetric responses corresponding 
to the oxidation of CIO" were examined. It was found that, any 
of the salt solutions K N 0 3 , K 2 S 0 4 or Na 2 S0 4 at the optimum 
concentration of 0.1 mol dm"3 could be used as a supporting 
electrolyte for the above determination. The study also revealed 
that, any pH in the range of 8.5 to 11 could yield satisfactory 
results. The anodic peak current at the working electrode 
potential of +1.030 V vs Ag/AgCl reference electrode was found 
to linearly increase with concentration of free chlorine up to 
300 mg dm3 (R 2 = 0.9996). The results indicated that the anodic 
peak current could be used as the basis for a simple, rapid and 
accurate determination of CIO" in waters in the concentration 
range from 1.0 mg dm3 to 300.0 mg dm3 with a high degree 
of reproducibility ( % RSD < 1.5). The results obtained with 
the proposed method for determination of concentrations of 
CIO" in commercial bleaching agents were in good agreement 
with those determined iodometrically (% difference <1.5). The 
method proved advantageous as it does not require purging of 
test solutions with nitrogen for removing of dissolved oxygen 
prior to voltammetric determinations. The applicability of 
square wave voltammetry in place of linear sweep voltammetry 
for determination of CIO" has also been demonstrated. 

Keywords: Free chlorine, graphite working electrodes, linear 
sweep voltammetry 

INTRODUCTION 

Hypochlorite is a powerful oxidizing agent and it 
is used for various purposes such as disinfection, 
bleaching and manufacturing processes1"4. It is an 
efficient and inexpensive oxidant and is available as 
sodium hypochlorite in alkaline solutions, with a pH of 
approximately 11. It can be easily synthesized, handled 

and stored. During disinfecting processes, it is added 
to potable waters and it undergoes hydrolysis in water 
forming hypochlorous acid and hypochlorous ions. 

NaOCl + H 2 0 s HOC1 + NaOH (1) 

K d 

HOC1 v C 1 0 + H + (2) 

(Dissociation Constant, Kd = 2.9 x 10"8 mol dm"3) 
As shown by equation (2), hypochlorous acid 

undergoes further dissociation and depending on the pH, 
concentrations of the two species, HOC1 and CIO", may 
vary. At pH > 8.5, CIO" is the dominant species and at 
pH < 5.5, HOC1 is the dominant species. 

Free chlorine is defined as the residual chlorine 
present as dissolved gas (Cl 2), hypochlorous acid 
(HOCI) and the hypochlorous anion. (CIO) in water 
bodies due to excessive usage of sodium hypochlorite 
during disinfection of water bodies. The three forms 
of chlorine exist together in equilibrium in water and 
their relative proportions are determined by pH and the 
temperature of the water. At the pH of 10 used in the 
present investigation free chlorine exists almost 100% as 
CIO". High concentrations of chlorine in drinking water 
can result in odour and taste. Currently there are growing 
concerns on the hazardous effects of free chlorine in 
water at higher concentrations. 

Several analytical methods such as iodometry and 
spectrophotometry are currently used to estimate CIO" 
concentration in waters 5. None of these methods is ideal 
for convenient and rapid determination of free chlorine. 

.An electro-analytical technique for determination of free 
chlorine6"9 is very attractive as it does not require special 

'Corresponding author 



26 K.A.S. Pathiratne et al. 

analytical reagents and can be conveniently employed in 
waters for online monitoring of CIO". 

The two reduction reactions given below has been 
used in the past for determination of CIO" in water 
electrochemically. 

CIO" + H 2 0 + 2e v = ^ CI" + 20H" (3) 

HC10 + 2e < = — " C l + O H (4) 

Use of these reactions have been found inconvenient as 
the reduction of dissolved O, in water occurs around the 
same potential region [equations (6) & (7) ] l 0 . 

O. + 41T + 4e ^ - ^ 2 H,0 E° = + 1.229 V (6) 

O. + 2W + 4e ^ —' H,0, E" = + 0.682 V (7) 

Two oxidation reactions [equations (8) & (9)] 6 have also 
been used successfully for determination of free chlorine 
in water. 

6CIO- f 3H,0 v- •• 2C10. - 4Cf + 6H" + 3/2 O, + 6e ( 8 ) 

6HCI0 + 3 H , O N2C10 5 + 4C1 + 12H'+ 3/2 0 2 + 6e (9) 

With this method, interference of dissolved 0 ,does 
not occur as oxidation potential of CIO" is well separated 
from the oxidation/reduction potential of dissolved 
oxygen. However, the method requires a relatively 
expensive supporting electrolyte, NaC10 4 and a working 
electrode (platinum, gold or glassy carbon) 6. Further, 
the limit of detection of the method was relatively high 
(4 mg dm ' ) . The method reported in this study uses less 
expensive supporting electrolytes (K.NO, or K 2 S 0 4 or 
Na,S0 4 ) together with an inexpensive graphite working 
electrode. Further, a lower limit of detection of 1.0 mg 
dm"' and higher linear range up to 300 mg dm"' were 
achieved with the proposed method. 

M E T H O D S A N D MATERIALS 

Reagents, chemicals and instrumentation: Sodium 
hypochlorite required was synthesized using analytical 
grade NaOH, K M n 0 4 and HC1 supplied from Fluka. 
The salts K N 0 3 , K.,S0 4 and N a , S 0 4 used were also of 
analytical grade supplied from Fluka. Double distilled and 
de-ionized water was prepared using an all glass distiller 
and a Barnstead deionizer at the resistivity 18 mf2 cm. 
pH of the solutions were measured using an Orion model 
294 pH meter and its electrodes. All glassware were 
soaked overnight in 5% HNO, acid solution and carefully 
cleaned with distilled and deionized water. They were 
air dried in a dust free environment prior to use. NaOCl 

March 2008 

was prepared by oxidizing HC1 with K M n 0 4 and passing 
the resultant gas into NaOH solution. Hypochlorite 
concentration of the resultant solution was determined by 
iodometric titration5. This solution was used as the stock 
NaOCl solution for the present investigation. 

EG & G Princeton Applied Research Model 394 
Electrochemical Trace Analyzer equipped with a three 
electrode cell was used for the present investigation. 
A graphite disk electrode (3 mm in diameter) was used 
as the working electrode, a platinum wire (2 mm in 
diameter) and Ag/AgCl reference electrode (Princeton 
Applied Research) were used as counter and reference 
electrodes respectively. All potentials were reported with 
respect to the Ag/AgCL reference electrode. 

Pretieatment of graphite working electrodes: The surface 
of the working electrode was polished initial ly with 0.3 u m 
alumina slurry followed by 0.05 um alumina slurry, 
carefully sonicated in de-ionized water for few minutes 
and then rinsed with de-ionized water. The polished 
electrode was pretreated in an electrolytic solution, which 
was used for the investigation, by scanning the working 
electrode potential in the range of - 0.800 V to + 1.200 V. 

Study of the dependence of voltammetric response on 
experimental variables: Dependence of the voltammetric 
response on the experimental parameters: deaeration, 
pH of solution, type of supporting electrolyte, 
concentration of supporting electrolyte, rate of scanning 
of working electrode potential and concentration of free 
chlorine were examined. Performance of the method 
was compared with that of square wave voltammetry. 
Results obtained with the proposed method under 
optimum conditions were evaluated with those obtained 
by the conventional iodometric method. 

RESULTS 

Voltammetric response and its dependence on purging 
with N 2 

Figure 01 shows the voltammograms obtained for the 
oxidation of CIO" at a concentration of 50 mg dm"' 
in 0.1 mol d m 3 K N 0 3 solution. The potential of the 
working electrode was scanned at a rate of 50 mVs"1 

from an initial potential value of - 0.800 V to a final 
potential value of + 1.200 V. The pH of the solution was 
10.0. The shape of the voltammogram in Figure 01(a) 
obtained after purging about 25cm 3 analyte solution 
with N 2 at an input pressure of ~ 5 psi for 15 min and 
blanketing the solution with a flow of N 2 gas is identical 
to the voltammogram in Figure 01(b) obtained with no 
purging of the analyte solution with N 2 prior to analysis. 

Journal of the National Science Foundation of Sri Lanka 36 (1) 



Linear sweep voltammetric determination of free chlorine 27 

-0.800 -0400 0.000 0400 0.800 

E / V v s . Ag/AgCl 

1.200 -0X00 -0.400 0.000 0.400 0.800 

E / V v s . Ag/AgCl 
1.200 

Figure 1: Cyclic voltammograms for a CIO'concentration of 50 mg dm 3 in 0.10 mol dm 3 KN0 3 solution obtained with graphite electrode 
(a) purging with nitrogen for 15 min. (b) with no nitrogen purging. Initial and final potentials were -0.800 V and + 1.200 V 
respectively. Scan rate was 50 mV s"1 and the pH of the solution was 10.0. 

0.600 0.700 0.800 0.900 1 000 

E/Vvs . Ag/AgCl 

1.100 1.200 

Figure 2: Cyclic voltammogram for a CIO" concentration of 150 mg dnr3 in 0.10 mol dm"3 KN0 3 

solution obtained with the graphite electrode. Initial and final potentials were + 0.600 V 
and + 1.200 V respectively. Scan rate was 50 mV s"1 and pH of the solution was 10.0. 

Peak current (70.90 uA) and peak potential (+1.030 V) 
corresponding to the oxidation of CIO" remain the same 
in the two voltammograms. Since the presence or 
absence of oxygen has no effect on the analytical peak 
at +1.030 V vs Ag/AgCl reference electrode, no oxygen 
removal is required for determination of free chlorine by 
the proposed method. 

Figure 02 shows a voltammogram obtained for a 
solution containing 150 mg d m 3 CLO" in 0.10 mol d m 3 

K N 0 3 solution at pH = 10.0. The solution was not purged 
with N 2 before analysis. The potential was scanned from 
+ 0.600 V to a final potential of + 1.200 V Vs Ag/AgCl 
reference electrode, at a scan rate of 50 mV s 1 . The 
voltammogram clearly shows that voltammetric response 
corresponding to oxidation of CIO" can be measured 
without purging with N r The scan range of + 0.600 V 

and + 1.200 V vs Ag/AgCl reference electrode could be 
used for the analysis of CIO". 

Effect of solution pH on voltammetric response 

Figure 03 shows the linear sweep voltammograms 
obtained for solutions at pH 1.0, 2.0, 4.0, 6.0, 8.0, 10.0, 
11.0 and 12.0. The concentration of CIO in each solution 
was 50 mg d m 3 . The potential of the working electrode 
was scanned from + 0.600 V to + 1.200 V at a rate of 
50 mV s 1 . No peak was observed at pH less than 2 as at 
low pHs the concentrations of CIO" is negligible. With 
increasing pH up to nearly 11.0, the signal has continuously 
increased as CIO' concentration in the medium increased 
with decreasing H + concentration. For the present 
analysis, pH of 10.0 was taken as the optimum pH of 
the solution. 

March 2008 Journal of the National Science Foundation of Sri Lanka 36 (1) 



28 K.A.S. Pathirutne et al. 

- 3 0 0 . 0 0 

0 . 6 0 0 0 . 7 0 0 0 . 8 0 0 0 . 9 0 0 1 . 0 0 0 

E / V vs. Ag/AgCl 

1 . 1 0 0 1 . 2 0 0 

F i g u r e 3 : L i n e a r s w e e p v o l t a m m o g r a m s at s e v e r a l d i f f e r e n t p H o f a n a l y t e s o l u t i o n ( a ) 1 .0 , ( b ) 2 . 0 , ( e ) 4 . 0 , ( d ) 6 . 0 , ( e ) 

8 . 0 . (1) 1 0 . 0 , ( g ) 1 1 . 0 a n d ( h ) 1 2 . 0 f o r a f r e e c h l o r i n e c o n c e n t r a t i o n o f 5 0 m g d m ' 3 i n 0 . 1 0 m o l d m " 3 K . N O , 

s u p p o r t i n g e l e c t r o l y t e f o r a g r a p h i t e w o r k i n g e l e c t r o d e . I n i t i a l a n d f i n a l p o t e n t i a l s w e r e + 0 . 6 0 0 V a n d 

+ 1 . 2 0 0 V r e s p e c t i v e l y . 

-200.00 

-100.00 -

I 0. 00-

100.00 

200.00 
5000 10000 15000 20.000 25.000 

1 — , 

- ( e ) 

- ( d ) 
' ( c ) 
'0) 
' ( a ) 

-0.800 -0.400 0.000 0.400 0.800 1.200 

E / V vs. Ag/AgCl 

F i g u r e 4 : L i n e a r s w e e p v o l t a m m o g r a m s f o r a C I O " c o n c e n t r a t i o n o f 5 0 m g d n r J in 0 .1 m o l d m " 1 K N 0 3 s u p p o r t i n g e l e c t r o l y t e w i t h the 

g r a p h i t e e l e c t r o d e . I n i t i a l a n d f i n a l p o t e n t i a l s w e r e - 0 . 8 0 0 V a n d + 1 . 2 0 0 V r e s p e c t i v e l y . S c a n ra tes w e r e : ( a ) 10 m V s ( b ) 

2 5 m V s ( c ) 5 0 m V s ( d ) 1 0 0 m V s>, ( e ) 2 5 0 m V s " \ ( 0 4 0 0 m V s '. I n s e r t s h o w s the R a n d i e S e v e i k p l o t o f a n o d i c p e a k 

c u r r e n t aga ins t the s q u a r e r o o t o f the s w e e p r a t e . 

March 2008 Journal of the National Science Foundation of Sri Lanka 36 (I) 



Linear sweep voltammetric determination of free chlorine 29 

Tablet 1: The effect of type of supporting electrolyte and its concentration on the peak potential and the peak current. (Free 
chlorine concentration was 50 mg dm"3 in 0.1 mol dm"3 KN0 3 supporting electrolyte. The working electrode was 
graphite. Initial and final potentials were -0.800 V and + 1.200 V respectively and scan rates was 50 mV s 1). 

Electrolyte Concentration of 
electrolyte / (mol dm'3) 

Peak potential / V Peak current / uA 

KN0 3 0.05 1.050 (±0.005) 66.90 (±0.10) 
0.10 1.030 (±0.006) 70.90 (±0.08) 

" 0.20 1.000 (±0.003) 72.70 (±0.07) 
0.30 0.970 (±0.003) 73.90 (±0.09) 

" 0.40 0.940 (±0.005) 74.60 (±0.10) 

0.05 1.060 (±0.003) 67.00 (±0.09) 
" 0.10 1.040 (±0.005) 71.20 (±0.08) 
" 0.20 1.010 (±0.003) 72.90 (±0.05) 
" 0.30 0.980 (±0.005) 74.00 (±0.10) 

0.40 0.950 (±0.003) 74.80 (±0.05) 

Na 2 S0 4 0.05 1.060 (±0.003) 67.10 (±0.05) 
0.10 1.040 (±0.003) 71.30 (±0.09) 
0.20 1.100 (±0.003) 73.00 (±0.05) 

" 0.30 0.980 (±0.003) 74.10 (±0.08) 
" 0.40 0.950 (±0.003) 74.95 (±0.01) 

Effect of type of supporting electrolyte and its 
concentration on voltammetric response. 

Table 01 gives the peak potentials and peak currents 
corresponding to the oxidation of CIO" in three different 
types of supporting electrolytes: K N 0 3 , KjSO^, and 
Na,SO. at five different selected concentrations. No 

2 4 

noticeable differences in peak potentials or peak 
currents were observed for the three different supporting 
electrolytes. However, with increasing concentration 
of the supporting electrolyte, a slight increase in peak 
currents was seen for all 3 electrolytes. The percentage 
increase in peak current (-5%) with increasing 
concentration from 0.05 mol d m 3 to 0.10 mol d m 3 was 
slightly higher than the percentage increase in current 
(~3%) over the concentration range from 0.1 mol d m 3 to 
0.4 mol d m 3 . For the present work, K N 0 3 was selected 
as the supporting electrolyte and 0.10 mol d m 3 was used 
as its optimum concentration. 

Effect of scan rate of working electrode potential on 
voltammetric response 

Figure 04 shows the voltammograms obtained for six 
different scan rates: 10, 25, 50, 100, 250 and 400 mV s"1 

of the working electrode potential. The initial and final 
potentials of -0.800 V and + 1.200 V were used for all 
scan rates. The peak potential shows a slight drift towards 
positive direction at low scan rates (10 to 50 mV s 1 )-
However, the peak potential remained at + 1.040 V for the 

rest of the scan rates. The peak current has continued to 
increase with increasing rates of potential scan. The plot 
of peak current against the square root of scan rate (Randle 
Sevcik plot) produced a straight line passing through 
origin (R 2 = 0.9993). In the present study, a complete 
investigation on the electrochemical reversibility of the 
reaction was not carried out. The present results indicated 
that the level of reversibility observed is sufficient for 
further investigation of the methods for its suitability for 
analytical applications. 

Variation of peak current with variation of CIO 
concentration 

Voltammograms obtained for several different CIO' 
concentrations 12.50, 25.00, 50.00, 75.00, 100.00, 
150.00, 225.00 and 300.00 mg d m 3 in 0.1 mol d m 3 

K N 0 3 supporting electrolyte are shown in Figure 05. 
The scan rate was 50 mV s"' and the initial potential 
and final potential were + 0.600 V and +1.200 V. With 
increase in concentration of CIO", the peak current 
had increased. A plot of peak current against the CIO" 
concentration had produced a straight line (R 2 = 0.9996) 
passing through origin indicating the analytical utility of 
the anodic peak current corresponding to the oxidation 
of CIO" for determination of free chlorine in water. The 
limit of detection (LOD) was estimated by measuring 
voltammetric response for 10 aliquots of chlorine free 
water at the peak potentials. The LOD of 1.0 mg dm"3 was 
calculated using the slope of the calibration curve and 
the standard deviation (S.D.) of the blank(s) as follows. 

Journal of the National Science Foundation of Sri Lanka 36 (I) March 2008 



30 K.A.S. Pathiratne et al. 

Figure 5: Linear sweep voltammograms for several concentrations of CIO': (a) 12.50 mg dm"3, (b) 25.00 mg dm3, (c) 50.00 
mg dnr\ (d) 75.00 mg dm"3, (e) 100.00 mg dm 3, (0 150.00 mg dm3, (g) 225.00 mg dm3, (h) 300.00 mg dm"3 (i) 
blank, in 0.10 mol dm 3 KNO, supporting electrolyte at graphite electrode. Initial and final potentials were +0.600 
V and + 1.200 V respectively. The scan rate was 50 mV s 1 . Insert shows a plot of anodic peak current versus the 
concentration of CIO'. 

-200.00 1 1 1 1 i i 
Epa= 1.040 V 

1 

-160.00 
(b) 

^ -120.00 
—. 

-80.00 Epa=+1030V 

-40.00 -

0.00 1 i 1 1 1 1 i 
0.600 0.700 0.800 0.900 1.000 1.100 

E / V vs. Ag/AgCl 

1.200 

Figure 6: Voltammograms for a CIO' concentration of 50 mg dm"3 in 0.10 mol dm"3 KN0 3 supporting electrolyte with a graphite 
working electrode (a) linear sweep voltammetry (scan rate of 50 mV/s) and (b) square wave voltammetry (frequency 
of 50 Hz and pulse height of 50 mV). Initial and final potentials were -0.800 V and + 1.200 V respectively. 

March 2008 Journal of the National Science Foundation of Sri Lanka 36 (I) 



Linear sweep voltammetric determination of free chlorine 31 

Table 02: Comparison of the analytical results obtained with the proposed method and the iodometric method, during 
determinations of CIO' in commercial bleaching solutions at three different concentration levels. 

Sample 

label 

Concentration of CIO" / mg dm 3 

Linear sweep voltammetric method Iodometric method 

1st 2nd 3rd Mean Standard 1st 2nd 3rd Mean Standard 
deviation deviation 

1 420.0 418.0 416.0 418.0 2.0 416.0 412.0 420.0 416.0 4 
2 211.5 209.2 205.5 208.7 3.0 209.2 210.4 209.5 207.7 2.5 
3 83.9 83.3 84.3 83.8 0.5 83.3 81.4 82.5 82.3 1.0 

w n n 3 x S.D. 
LOD = 

Slope 

The concentration of CIO" that gives 5% deviation 
from nominal sensitivity was used to determine the upper 
limit of calibration (300 mg d m 3 ) curve for the present 
method. 

Comparison of performance: linear sweep 
voltammetry versus square wave voltammetry 

Figure 06 shows a nearly 100 % increase in peak current 
with square wave voltammetry compared to linear sweep 
voltammetry forthe 50 mg dm' 3 free chlorine concentration 
in 0.10 mol dm' 3 K N 0 3 supporting electrolyte. The pulse 
height and frequency for the square wave voltammetry 
were 50 mV and 50 Hz respectively. This indicates the 
possibility of using square wave voltammetry with an 
improved sensitivity for determination for free chlorine 
in aqueous environments. 

Validation of analytical results and analysis of real 
sample 

Table 02 gives the results obtained for CIO" contents 
in a commercially available bleaching solution at three 
different concentration levels measured in triplicate 
using the proposed linear sweep voltammetric method 
and the iodometric method. The percentage differences 
of the results between voltammetric method and the 
iodometric method were 0.48 %, 0.48 % and 1.80 % for 
the three concentration levels ( 1 , 2 and 3 respectively). 
In addition, the standard deviations of the results for the 
voltammetric determination were lower than those for 
the iodometric method. 

C O N C L U S I O N 

Linear sweep voltammetry with a graphite electrode can 
be used for determination of free chlorine concentrations 

in the range of 1.0 - 300.0 mg d m 3 with a high degree of 
reproducibility. Any of the electrolytes K N 0 3 , K 2 S 0 4 and 
Na,SO. at a concentration of 0.1 mol d m 3 can be used as 

2 4 

the supporting electrolyte for the determination. Removal 
of oxygen, by purging with nitrogen, is not required 
for the proposed method. Square wave voltammetry in 
place of linear sweep voltammetry can also be used if 
necessary to determine concentration of CIO' lower than 
1.0 mg dm' 3. 

References 

1. White G.C. (1986). Handbook of Chlorination, second 
edition. Van Nostrand, Recinhold, New York. 

2. Galal-Gorchev H. (1996). Chlorine in water disinfection. 
Pure & Applied Chemistry 68(9): 1731 -1735. 

3. Fauvarque J. (1996). The Chlorine Industry. Pure & 
Applied Chemistry 68(9): 1713-1720. 

4. Solomon K.R. (1996). Chlorine in the bleaching of pulp 
and paper. Pure & Applied Chemistry 68(9): 1721-1730. 

5. Mendham J., Denney R.C., Barnes J.D., Thomas M.J.K., 
(2004). Vogel's Textbook of Quantitative Chemical 
Analysis, sixth edition, p.435. Pearson Education, 
Singapore. 

6. Kodera R , Umeda M. & Yamada A. (2005). Determination 
of free chlorine based on anodic voltammetry using 
platinum, gold and glassy carbon electrode. Analytica 
ChimicaActa 537:293-298. 

7. Kodera R , Kishoka S . , Umeda M. & Yamada A. 
(2004). Electrochemical detection of free chlorine using 
anodic current. Japanese Journal of Applied Physics 
43(7A):L913-L914. 

8. Kishoka S . , Kosugi T . & Yamada A. (2004). Electroc­
hemical determination of a free chlorine residual using 
cathodic potential-step chronocoulometry. Electroanalysis 
17(8): 724-726. 

9. Tsaousis A.N. & Huber CO. (1985). Flow-injection 
amperometric determination of chlorine at a gold 
electrode. Analytica ChimicaActa 178:319-323. 

10. Skoog D.A., West D.M., Holler F.J. & Crouch S.R. (2004). 
Fundamental of Analytical Chemistry, eighth edition p. A 
13. Thomoson Asia (pte.) Ltd., Singapore. 

Journal of the National Science Foundation of Sri Lanka 36(1) March 2008