{Electrochemical measurements of ascorbic acid based on graphite screen printed electrode modified with La3+/Co3O4 nanocubes transducer}


http://dx.doi.org/10.5599/jese.643  197 

J. Electrochem. Sci. Eng. 9(3) (2019) 197-206; http://dx.doi.org/10.5599/jese.643 

 
Open Access: ISSN 1847-9286 

www.jESE-online.org 
Original scientific paper 

Electrochemical measurements of ascorbic acid based on 
graphite screen printed electrode modified with La3+/Co3O4 
nanocubes transducer 

Mohammad Reza Aflatoonian1,2,, Somayeh Tajik1,, Behnaz Aflatoonian3,  
Hadi Beitollahi4 
1Research Center for Tropical and Infectious Diseases, Kerman University of Medical Sciences, 
Kerman, Iran 
2Leishmaniasis Research Center, Kerman University of Medical Sciences, Kerman, Iran 
3Neuroscience Research Center, Kerman University of Medical Sciences, Kerman, Iran 
4Environment Department, Institute of Science and High Technology and Environmental Sciences, 
Graduate University of Advanced Technology, Kerman, Iran 

Corresponding authors: m.aflatoonian97@gmail.com; Tel.: +98 3426226613; Fax: +98 3426226617;  
mTajik_s1365@yahoo.co 

Received: December 4, 2018; Revised: February 23, 2019; Accepted: February 26, 2019 
 

Abstract 
Electrochemical characterization of ascorbic acid oxidation on a graphite screen printed 
electrode (SPE) modified with La3+/Co3O4 nanocubes is performed by applying cyclic 
voltammetry (CV), chronoamperometry (CHA), and differential pulse voltammetry (DPV) 
techniques. Synthesized La3+/Co3O4 nanocubes for SPE modification, La3+/Co3O4/SPE, enhance 
the ascorbic acid electrooxidation kinetics by reducing the anodic overpotential. Excellent 
La3+/Co3O4/SPE electrochemical properties provide sensitive ascorbic acid voltammetric 
determination with low detection limit, good stability and quick response towards 
electrooxidation of ascorbic acid as compared to bare SPE. Under optimized conditions, DPV 
current demonstrates a linear response for ascorbic acid over a concentration range of 1.0 to 

900.0 M with a correlation coefficient of 0.9997, and detection limit (LOD) (S/N = 3) = 0.3 M. 
The proposed procedure offers a potential application for producing the sensor with good 
repeatability. Also, fast response of fabricated sensor can allow a real-time analysis of real 
samples. 

Keywords 
Ascorbic acid; electrochemical characterization, La3+/Co3O4 nanocubes; graphite screen printed 
electrode; voltammetry 

 

http://dx.doi.org/10.5599/jese.643
http://dx.doi.org/10.5599/jese.643
http://www.jese-online.org/
mailto:m.aflatoonian97@gmail.com
mailto:m.aflatoonian97@gmail.com
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J. Electrochem. Sci. Eng. 9(3) (2019) 197-206 ELECTROCHEMICAL MEASUREMENTS OF ASCORBIC ACID 

198  

Introduction 

Ascorbic acid is a water soluble vitamin (vitamin C), widely present in many biological systems, 

fruits and vegetables. Beyond its function in collagen formation, ascorbic acid is known to increase 

absorption of inorganic iron, to have essential roles in the metabolism of folic acid, some amino acid 

and hormones, and to act as an antioxidant 1-4. Deficiency of ascorbic acid will cause scurvy 

disease 2-5. It is administered in the treatment of many disorders, including Alzheimer's disease, 

atherosclerosis, cancer, and infertility 3-6. In the light of these facts, determination of low 

concentrations of ascorbic acid without any interference from other biomolecules is a very 

important subject in pharmacology fields 5-8. 

Numerous approaches such as fluorescence 9, UV spectroscopy 10, chemiluminescence 11, 

electrophoresis 12, and liquid chromatography 13 have been reported for the determination of 

ascorbic acid. These methods suffer from the lack of specificity and are prone to interferences with 

other reducing agents in the sample. Moreover, some complications in chromatography 

performances were detected, such as selecting a proper column or a mobile phase with liquid 

chromatographic methods, costly instruments, long response time, difficult procedure, and low 

detection ability. Since ascorbic acid is an electroactive compound, electrochemical techniques for its 

detection has received a considerable interest 14-16. Electrochemical methods came to attention 

due to their high sensitivity, easy operation and low cost 17-23.  

Nowadays, a variety of nanoparticles with numerous properties, such as high speed, minor size, 

smaller distances for electrons to travel, lower power, and lower voltages, made important advances 

in the field of nanotechnology. Thus, the utilization of nanomaterials such as metal nanoparticles, 

metal oxide nanoparticles, magnetic nanomaterials, carbon materials, quantum dots and 

metallophthalocyanines enhanced the electrochemical signals of biocatalytic events occurring at the 

electrode/electrolyte interface 24,25. Along with nanoscience and nanotechnology development, 

there were numerous trials to employ innovative nanomaterials in constructing modified electrodes 

26-28. Nanostructured metal oxides were also investigated in recent years as electrochemical sensor 

materials, showing promising results owing to several benefits of the materials such as high surface 

area, workability, and increasing synthetic accessibility 29-32.  

Currently, the screen printed electrode (SPE) has become an interesting and widely applied 

electrode material. SPEs have already been successfully used as electrochemical sensors for various 

researches due to their simplicity and minimum sample preparation. In addition, the main benefit 

of SPE is based on its single use, after which it is discarded. However, the limitation of SPE is small 

surface area of the working electrode leading to the lack of sensitivity. To overcome this problem, 

the electrode modification is necessary 33,34. 

In this study, La3+/Co3O4 nanocubes modified SPE has been exploited for ascorbic acid sensing 

and the analytical performance of the suggested sensor for ascorbic acid determination in real 

samples is evaluated. 

Experimental 

Chemicals and apparatus  

Electrochemical experiments were performed using an Autolab potentiostat/ galvanostat 

(PGSTAT 302N, Eco Chemie, the Netherlands). General purpose electrochemical system software 

was used to control the system. The screen printed electrode (DropSens, DRP-C110, Spain) contains 

three main parts which are a graphite counter electrode, a silver pseudo-reference electrode, and a 

graphite working electrode. The pH values were measured by a Metrohm 710 pH meter. The 



Mohammad Reza Aflatoonian et al. J. Electrochem. Sci. Eng. 9(3) (2019) 197-206 

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morphology of the products was observed using a Philips XL30 scanning electron microscope (SEM). 

Prior to SEM analysis, samples were loaded on a gold film prepared by an SCD005 BAL-TEC Sputter 

Coater. XRD studies were conducted on a Rigaku D/max 2500 V instrument with a graphite 

monochromator and a Cu target. The FT-IR spectra were prepared by use of a Bruck Equinox 55 

spectrophotometer and the KBr pellet of samples were used. All reagents were purchased from 

Merck (Darmstadt, Germany) in analytical grade. Buffer solutions within the range of 2.0–9.0 were 

prepared using orthophosphoric acid and its salts.  

Synthesis of La3+/Co3O4 nanocubes 

In a typical synthesis, 25 mL of ammonia solution (28-30 %, Reagent Chemicals) was first mixed 

with ultra-pure water (1/1, v/v). Then, 0.05 g of poly(vinylpyrrolidone) (PVP; M.W. 58,000, Reagent 

Chemicals) was dissolved in the solution. After shaking for a few minutes, 0.364 g of cobalt nitrate 

hexahydrate (Co(NO3)26H2O) and 0.043 g of lanthanum nitrate hexahydrate (La(NO3)26H2O) were 

added into the reaction medium. After sonication, a browny transparent solution was obtained, 

which was then transferred into 100 mL teflon-lined stainless steel autoclave. The autoclave was 

kept in an electric oven at 180 °C for 6 h, after which the autoclave was taken out and cooled 

naturally to room temperature. After that, the black precipitate was harvested and washed with 

ultra-pure water several times via centrifugation. The product was then dried at 60 °C overnight, 

before being calcined at 300 °C for 2 h in air to be converted into La3+/Co3O4 nanocubes. 

Preparation of the electrode  

In order to prepare the modified electrode, the surface of bare SPE was coated by a thin film of 

La3+/Co3O4 nanocubes as follows: in a simple procedure, 1 mg La3+/Co3O4 nanocubes were dispersed 

in 1 mL aqueous solution by ultrasonication for 15 min. Then, surface of SPE working electrode was 

treated with 2 µl of the prepared suspension. After drying at room temperature, the modified 

electrode was ready to use.  

Preparation of real samples 

One milliliter of a vitamin C ampoule (Darou Pakhsh Company, Iran, contained 1 mg/mL of 

ascorbic acid) was diluted to 10 mL with 0.1 M PBS (pH 7.0); then, different volume of the diluted 

solution was transferred into each of a series of 25 mL volumetric flasks and diluted to the mark 

with PBS. The ascorbic acid content was analyzed by the proposed method using the standard 

addition method. 

Five vitamin C tablets (labeled 250 mg per tablet, Osvah Pharmaceutical Company, Iran) were 

grinding. Then, the tablet solution was prepared by dissolving 400 mg of the powder in 25 mL water 

by ultrasonication. After that, different volume of the diluted solution was transferred into a 25 mL 

volumetric flask and diluted to the mark with PBS (pH 7.0). The ascorbic acid content was analyzed 

by the proposed method using the standard addition method. 

Five effervescent tablets of vitamin C (labeled 500 mg per tablet, Hakim Pharmaceutical 

Company, Iran) were grinded completely. After that 500 mg of the powder was dissolved in 25 mL 

water using ultrasonication and different volume of the diluted solution was transferred into a 25 

mL volumetric flask and diluted to the mark with PBS (pH 7.0). The ascorbic acid content was 

analyzed by the proposed method using the standard addition method. 

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Result and discussion 

Nanostructures characterization 

Figure 1 displays the FT-IR spectrum of La3+/Co3O4 nanocubes sample in the frequency range of 

400–4000 cm-1. The FT-IR spectrum of La3+/Co3O4 nanocubes showed strong vibrational bands in the 

lower frequency regions (about 400-600 cm-1), ascribable to the vibration of metal–O. The 

absorption seen at ~3389 cm-1 is thought to be due to the symmetric vibration of the -OH groups of 

the absorbed H2O molecules. The peak at ~1632 cm-1 corresponds to O-H groups, again related to 

adsorbed H2O molecules 34.  
 

 
Fig. 1. FT-IR spectrum of La3+/Co3O4 nanocubes. 

The main characteristic diffraction peaks of La3+/Co3O4 nanocubes are consistent with the 

standard patterns of Co3O4 (JCPDS card No. 71-0816) with cubic spinel phase, suggesting that the 

doping of La does not change the backbone of pristine Co3O4 (Figure 2). By increase of La content in 

Co3O4, the characteristic peak at 2 =37.3° becomes weaker and slightly shifted to small-angle 

reflections. The introduction of La ions with f-block electronic and large atomic radiuses into the 

Co3O4 grain boundary, causes the loss of atomic degree of ordering of Co3O4, thereby contributing 

to the limited growth of the grain, grain refinement and decrease of crystallinity. 
 

 
2 / o 

Fig. 2. XRD pattern of La3+/Co3O4 nanocubes 

The broadness of diffraction peaks suggests the nano-sized nature of the product and the average 

crystallite size (T) was calculated as 67.0 nm using the Debye–Scherrer formula T = 0.9  /  cos , 

where λ is the wavelength of the X-ray radiation (1.54056 Å for Cu lamp),  is the diffraction angle 

and  is the full width at half-maximum (FWHM) [35]. 



Mohammad Reza Aflatoonian et al. J. Electrochem. Sci. Eng. 9(3) (2019) 197-206 

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The morphology of the product was examined by SEM. Figure 3 depicts SEM pictures of 

La3+/Co3O4 nanoparticles. It can be observed from Figure 3, that nanoparticles which are nanocubes 

are less than 70 nm. 
  

 
Fig. 3. SEM images of La3+-doped Co3O4 nanocubes for A) high concentration,  

B) low concentration 

Electrochemical profile of the ascorbic acid on the La3+/Co3O4/SPE  

In order to investigate the electrochemical behaviour of ascorbic acid and obtain the accurate 

results, it is essential to determine the optimized pH value since its electrooxidation is pH dependent 

process. For this purpose, the experiments were performed using the modified electrode at various 

pH values ranging from 2.0–9.0 (Figure 4).  
 

  
Fig. 4. Plot of Ip vs. pH (2.0-9.0) in 0.1 M PBS in the presence of 900.0 μM ascorbic acid  

at the scan rate 50 mV s-1. 

According to Figure 4, the best results for electro-oxidation of ascorbic acid are achieved at pH 7.0. 

Figure 5 presents cyclic voltammograms (CVs) obtained for La3+/Co3O4/SPE (curve a) and unmodified 

SPE (curve b) in the presence of 900.0 μM ascorbic acid. Comparing CV results of modified and bare 

SPE revealed that the maximum oxidation of ascorbic acid observed at 300 mV for La3+/Co3O4/SPE, is 

about 70 mV more negative for unmodified SPE. When oxidation current peak values of ascorbic acid 

at La3+/Co3O4/SPE (1 µA) and bare SPE (0.5 µA) are compared, an extensive (about 100 %) 

enhancement for La3+/Co3O4/SPE relative to the bare SPE is observed. In other words, the results 

clearly indicate that La3+/Co3O4 nanocubes improve the ascorbic acid oxidation signal. 
 

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Fig. 5. CVs of (a) La3+/Co3O4/SPE and (b) unmodified SPE in 0.1 M PBS (pH 7.0) in the presence 

of 900.0 μM ascorbic acid at the scan rate 50 mV s
-1. 

Effect of potential scan rate  

As shown in Figure 6, investigation of the effect of potential scan rates on the oxidation currents of 

ascorbic acid demonstrated that increasing of the scan rate results in increased oxidation peak current 

values (Ip). The observed linear relation between Ip and the square root of the potential scan rate (ν1/2) 

indicates that oxidation of ascorbic acid is a diffusion-controlled process.  
 

 
Fig. 6. CVs of La3+/Co3O4/SPE in 0.1 M PBS (pH 7.0) containing 800.0 µM ascorbic acid at various scan rates 
(ν). Numbers 1-19 correspond to 10, 20, 30, 40, 50, 60, 70, 80, 90, 100, 200, 300, 400, 500, 600, 700, 800, 

900 and 1000 mV s-1, respectively. Inset: Variation of anodic peak current vs. ν1/2 

Chronoamperometric analysis 

The analysis of chronoamperometry (CHA) for ascorbic acid samples was performed by use of 

La3+/Co3O4/SPE vs. Ag/AgCl/KCl (3.0 M) at 0.35 V. CHA results obtained for different concentrations 

of ascorbic acid samples in PBS (pH 7.0) are depicted in Figure 7. The Cottrell equation for 



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chronoamperometric analysis of electroactive moieties under mass transfer limited conditions is 

expressed as follows 36: 

I =nFAD1/2cbπ-1/2t-1/2 

where D is diffusion coefficient, cm2 s-1, and Cb refers to the bulk concentration, mol cm−3. 

Experimental results of I vs. t−1/2 are plotted in Figure 7A as the best fitted curves for different 

concentrations of ascorbic acid. The resulting slopes of the straight lines in Figure 7A were then plotted 

against the concentration of ascorbic acid in Figure 7B. Finally, regarding the resulting slope and 

Cottrell equation, the mean value of D was determined as 1.010-6 cm2 s-1. This value is comparable 

with the values reported in some previous works (2.210–6 cm2 s-1 [1] and 5.6610–6 cm2 s-1 [37]). 
 

  
Fig. 7. CHAs of La3+/Co3O4/SPE in 0.1 M PBS (pH 7.0) for different concentrations of ascorbic acid. Numbers 
1–4 correspond to 0.1, 0.5, 1.0 and 1.5 mM of ascorbic acid. Insets: (A) Plots of I vs. t-1/2 obtained from CHAs 

1–4. (B) Plot of straight lines slope against ascorbic acid concentration 

Calibration curve 

The modified electrode (La3+/Co3O4/SPE) was applied as the working electrode in the 

concentration range of ascorbic acid in 0.1 M PBS and subdued to differential pulse voltammetry 

(DPV) since this technique in analytical applications offers advantages of enhanced sensitivity and 

better efficiency (Figure 8). According to the results, a linear relationship exists between the peak 

currents and concentrations of ascorbic acid within the concentration range of 1.0-900.0 µM with 

the correlation coefficient of 0.9997. The detection limit of 0.3 µM was obtained.  

Interference study  

The influence of various substances as compounds potentially interfering with the determination 
of ascorbic acid was studied in the presence of 50.0 µM ascorbic acid. The tolerance limit was 
defined as the maximum concentration of the interfering substance that caused an error less than 
±5 % in the determination of ascorbic acid. 

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Fig. 8. DPVs of La3+/Co3O4/SPE in 0.1 M PBS (pH 7.0) containing different concentrations of ascorbic acid. 

Numbers 1-20 correspond to 1.0-900.0 μM of ascorbic acid. Inset: Plot of the peak current as a function of 
ascorbic acid concentration. 

According to the results, uric acid, L-serine, L-phenylalanine, ethanol, benzoic acid, isoproterenol, 

methanol, serotonin, L-asparagine, acetaminophen, NADH, saccharose, urea, glucose, L-lysine, 

L-glycine, carbidopa, caffeine, levodopa, fructose, L-threonine, lactose, L-histidine, L-proline, S2−, Mg2+, 

SO42−, NH4+, F− and Al3+ did not show interference in the determination of ascorbic acid. 

Analysis of real samples 

To assess the applicability of this modified sensor for the determination of ascorbic acid in 

vitamin C ampoule, vitamin C tablet and vitamin C effervescent tablet, the proposed method was 

tested in water samples using the described procedure. In this process, the standard addition 

method was employed, and the results are given in Table 1.  

Table 1. Determination of ascorbic acid in vitamin C ampoule, vitamin C tablet and vitamin C effervescent tablet 

Sample 
Concentrations, μM (n=5) 

Recovery, % RSD, % 
Spiked Found 

Vitamin C ampoule 

0 10.0 - 3.4 

5.0 14.8 98.7 1.7 

10.0 20.4 102.0 2.1 

15.0 24.5 98.0 1.5 

20.0 30.9 103.0 2.9 

Vitamin C tablet 

0 5.0 - 2.4 

10.0 15.2 101.3 1.7 

15.0 20.1 100.5 3.4 

20.0 24.3 97.2 2.1 

25.0 30.6 102.0 3.2 

Vitamin C effervescent 
tablet 

0 5.0 - 2.8 

10.0 15.3 102.0 3.1 

15.0 19.8 99.0 2.9 

20.0 24.3 97.2 2.6 

25.0 30.5 101.7 1.6 



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According to the results, the recovery of ascorbic acid is satisfactory and the reproducibility of 

the results is approved by the mean relative standard deviation (RSD.). 

The repeatability and stability of La3+/Co3O4/SPE 

The long-term stability of the La3+/Co3O4/SPE was evaluated over 3-week period. After the modified 

electrode was stored for 3 weeks in atmosphere at room temperature, the experiments were performed 

again. According to cyclic voltammograms, the peak potential for ascorbic acid oxidation remained 

unchanged and a decrement of less than 2.2 % compared with initial response was observed.  

The antifouling properties of the modified electrode towards ascorbic acid oxidation and its 

oxidation products were studied by recording CVs. Voltammograms were recorded in the presence 

of ascorbic acid after cycling the potential 20 times at a scan rate of 50 mV s-1. Results demonstrated 

that peak potentials remained unchanged and the currents decreased by less than 2.1 %. According 

to the results, application of modified La3+/Co3O4/SPE provides increased sensitivity and decreased 

fouling effect of the analyte and its oxidation product.  

Conclusion 

La3+/Co3O4 nanocubes-SPE demonstrated an outstanding behavior toward ascorbic acid oxidation 

in the aqueous PBS (pH 7.0) solution. Our investigation exhibited that in the case of the unmodified 

SPE, the voltammogram of ascorbic acid displays just a small hump peak, but after modification of the 

electrode with La3+/Co3O4 nanocubes, the oxidation peak currents of ascorbic acid are significantly 

enhanced. This technique offers a number of advantages compared to the other published 

electrochemical methods, such as simplicity in the preparation of the modified electrode and its high 

selectivity. The modified electrode represented appropriate performance in detecting ascorbic acid 

and revealed excellent stability and reproducibility. By DPV determination, the detection limit of 

ascorbic acid was estimated as 0.3 µM. Based on the electrochemical oxidation, the quantitative 

determination of ascorbic acid in real samples was developed by a simple, rapid, selective and 

sensitive DPV technique. These properties indicate that the La3+/Co3O4 nanocubes modified electrode 

is a good electrochemical sensor for the ascorbic acid determination.  

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