ResearchJournalofChemicalSciences______________________________________________ISSN2231-606XVol. 4(8), 88-93,August (2014) Res.J.Chem.Sci. International Science Congress Association        
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Syneristic effect ofC. Papaya Leaves Extract-Zn2+ in Corrosion Inhibition of Mild Steel in Aqueous Medium Kavitha N., Manjula P. and Anandha kumar N.1 A.P.A.College of arts and culture, palani-624 601, Dindiguldistrict, Tamil Nadu, INDIA A.P.A.Colege for women, Palani, Dindiguldistrict, Tamil Nadu, INDIAAvailable online at: 
www.isca.in, www.isca.me
Received 6th August 2014, revised 10th August 2014, accepted 18th August 2014 Abstract The corrosion inhibition of aqueous extract of C. Papaya leaves on mild steel in 60 ppm Cl ion containing aqueous medium was studied by using inhibition efficiency and degree of surface coverage. The most suitable inhibitor concentration was found to be 2 ml of C. Papaya leave extract with inhibition efficiency (IE) of 91% at Zn2+ (50 ppm) by the weight loss method.Synergism parameters have been calculated to evaluate the synergistic effect existing between C. Papaya leave extract and Zn2+. The influence of immersion time and P has also been investigated. The protective film has been analyzed using Fourier transform infrared (FTIR) spectroscopy.Keywords: Synergistic effect, C. Papaya, corrosion inhibition, weight loss method. Introduction Corrosion can be defined as the degradation of material when it comes in contact with the environment. The corrosion inhibition of metals can be achieved by the addition of inhibitors to the system that prevent corrosion from taking place on the metal surface. Inorganic compounds like chromate, phosphates, molybdates, etc., and the variety of the organic compounds containing hetero atoms like nitrogen, sulphur, and oxygen are being investigated as corrosion inhibitors. But the toxicity of organic corrosion inhibitors to the environment has prompted the search for green corrosion inhibitors as they are biodegradable, renewable, and free from toxic compounds as well as heavy metals. Number of plant sources have been reported as a effective corrosion inhibitors, such as, Polyalthia Longifolia, Oxystelma Esculentum, Eclipta alba, Nelumbo nucifera, Red Onion, Uncariagambir, Ocimum gratissimum, etc., Like those inhibitors, many investigations are done on the corrosion inhibition of Papaya (pawpaw) of the Caricaceae family contains numerous chemical constituents which include the fermenting agent myrosin, alkaloids, rutin, resin, tannins, carpine, dehydrocarpines, pseudocarpine, flavonols,benzylglucosinolate, linalool, malic acid, methyl salicylate, chymopapain, calcium, iron, magnesium, manganese, phosphorous, potassium, zinc, beta-carotene, B-vitamins and vitamins A, C, and E, anthraquinones (bound and free ), philobatinins and saponins. The corrosion inhibition of Carica papaya in sulfuric acid media on mild steel was studied by using gravimetric and gasometric techniques10. Corrosion inhibition of C. Papaya in HCl medium on aluminium was studied, using weight loss, thermometric and hydrogen evolution techniques 11. The corrosion inhibition of C. Papaya and azadirachta indica leaves in HSO medium on mildsteel were compared by weight loss techniques 12. The effect of C.papaya and C. Sinensis on the corrosion of  (duplex) brass in 1M HNO was studied by weight loss/ corrosion rate and potential measurement techniques13. In this work, the inhibitory action of various concentrations of c.papaya leave (CPL) extract with Zn2+ ions are analyzed in the presence of 60 ppm Cl ion containing aqueous corrosive medium which is normally present in the cooling water systems by using weight loss and surface coverage () methods.Material and Methods Preparation of Specimen: Mild steel specimens of size 1.0 cm ×4.0 cm ×0.2 cm and chemical composition 0.026 % sulphur, 0.06% phosphorous, 0.4 % manganese, 0.1% carbon and the rest iron were polished to a mirror finish and degreased with acetone and used for the weight loss method and surface examination studies.  Preparation of C. Papaya leaves (CPL) extract: An aqueous extract of CPL was prepared by grinding 10g of CPL, with double distilled water. The solid impurities were removed by filtration process. Then the extract was made up to 100ml5, 14-16. Weight–loss method: Mild steel specimens were immersed in 100 ml of the aqueous medium containing 60 ppm Cl ions in various Concentrations of the inhibitor CPL extract in the absence and presence of Zn2+ for one day. The Inhibition efficiency (IE %) was calculated using the equation, Inhibiton efficiency, 
	\n
\r\rSurface coverage, 	\n
  
ResearchJournalofChemicalSciences___________________________________________________________ISSN2231-606XVol. 4(8), 88-93,August (2014) Res.J.Chem.Sci.   International Science Congress Association 
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Where Wo and W are the weight loss for mild steel in the absence and presence of inhibitor. Determination of corrosion Rate: The corrosion rate (CR) is directly proportional to the weight loss / cm in a specified time and was calculated by the formula, 
Where, W = weight loss in mg., D = density of mild steel (7.86 g / cm for mild steel), A = Area in cm,  T = Exposure time in hours, Trends of CR and IE are graphically evaluated. Calculation of synergistic factor (S) 
Where  and  are the surface coverage of compounds A and B respectively, acting alone and AB is the experimentally observed combined surface coverage of the solution containing both A and B. Results and DiscussionWeight loss method: Effects of concentration on Inhibition Efficiency:  When the concentration of the plant extract increases, the fraction of surface covered by the adsorbed molecule also increases which results into an increase in the inhibition efficiency. As Shown in figure 1, the maximum inhibition efficiency of 91% is reached only for the 2ml of CPL extract – Zn2+ (50 ppm), above which further increase in extract concentration decreases the inhibition efficiency. As in table 1, 2ml of CPL extract shows 32% inhibition efficiency and 50 ppm Zn2+ shows only 59% inhibition efficiency in 60 ppm Cl ion containing aqueous medium. But their combination provides 91% IE. This suggests that a synergistic effect exists between CPL extract & Zn2+. Figure-1 Concentration of Zn2+ on Inhibition efficiency(%)Table-1 Corrosion rate (CR) and Inhibition efficiency (IE) of mild steel immersed in 60ppm Cl- containing aqueous medium by weight loss method S. No Concn. of CPL extract (ml) Zn
2+
ppm 
0 10 25 50 
%IE Corr. rate×103 mmpy %IE Corr. rate×103 mmpy %IE Corr. rate×103 mmpy %IE Corr. rate×103 mmpy 
1 0 - 97.64 27 74.39 45 60.44 59 41.85 
2 2 32 69.75 45 55.79 82 18.59 91 9.29 
3 4 -18 120.89 9 92.99 27 74.39 71 18.59 
4 6 -59 162.73 -9 111.59 23 79.04 73 27.89 
5 8 -82 185.98 -32 134.84 -32 134.84 59 41.84 
Immersion period: One day Inhibitor: C. Papaya leaves (CPL) extract (ml) + Zn2+ (ppm) 





	Inhibition efficiency (%)concentration of Zn 2+(ppm)
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\n\n\r\n
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ResearchJournalofChemicalSciences___________________________________________________________ISSN2231-606XVol. 4(8), 88-93,August (2014) Res.J.Chem.Sci.   International Science Congress Association 
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Effects of concentration on corrosion rate: As shown in figure 2, it was observed that the rate of corrosion of mild steel decreases with increase of various concentrations of CPL extract - Zn2+ (50 ppm), indicating that the aqueous extracts of CPL inhibited the corrosion of mild steel in aqueous medium containing 60ppm Clion.  Synergism parameter: Every inhibitor has its individual inhibition efficiency that may be high or low depends on the group of atoms present in the inhibitor molecule. If more than one, inhibitors are used for the study, which must be checked whether the synergistic behaviour is offered between the inhibitors or not17. Actually, many investigations concerning synergistic inhibition have been carried out18-20. Synergistic factor (S) is calculated for the mixture containing various concentration of CPL extract as A & Zn2+ (50ppm) as B. 
Where A andB are the surface coverage of compounds A & B respectively, acting alone and AB is the experimentally observed combined surface coverage of the solution containing both, A and B. If inhibitors, A and B have no effect on each other & adsorb at metal –solutions interface independently, then the value of synergistic factor, S=1. When the value of S �1, shows synergistic effect and S1 shows antagonistic effect between the inhibitors. From the table 2, it was cleared that the synergistic factor S&#x-3.3;女 1. Thus a good synergistic effect was exhibit between various concentrations of CPL extracts and Zn2+ (50ppm). Effect of pH on IE of CPL extracts - Zn2+ system: It is seen from table 3, that at pH 7, the CPL extracts (2mL) – Zn2+ (50 ppm) system has 91% IE. When pH is lowered to 4 the IE is decreased to 28%. When the pH is increased to 9.2, the IE is increased to 65% as in figure 3. This is due to the presence of phenolic compounds21 such as ferulic acid, caffeic acid, chlorogenic acid found in leaves of C. Papaya22. Figure-2 Concentration of Zn2+ on corrosion rate (mmpy)Table-2 Synergism parameters (S) for various concentration of CPL extracts and Zn2+(50 ppm) Zn
2+
(50ppm) 

 CPL extract 

 CPL extract + Zn
2+
(50ppm) 

AB
0.5909 0.3182 0.9090 3.065 
0.5909 -0.1818 0.8181 2.6579 
0.5909 -0.5909 0.7272 2.3857 
0.5909 -0.8182 0.5909 1.2588 
 
204060801001201401601802000102030405060
Corrosion ratex103(mmpy)   
Concentration of Zn 2+ (ppm)
0 ml C.Papayaextract
2 ml C. Papaya extract
4 ml C.papaya extract
6 ml C.Papaya extract
8 ml C.papaya extract
ResearchJournalofChemicalSciences____
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Vol. 4(8), 88-93,August (2014)
 
  International Science Congress 
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Table-3 Effect of P on the CPL extract (2ml) -
Zn
Immersion Time: One 
day
Inhibition Efficiency (%)
 
P
H
 7 
SYSTEM: 60 ppm Cl
-
+ CPL extract (2ml) –Zn2+ (50 ppm) 91%
 
Effect of immersion time on inhibition
 
figure 4, it was clear that, the aqueous extract
 
Zn2+ (50ppm) have shown excellent 
corrosion
 
Influence
Effect 
of
Analysis of FTIR spectra: Papaya leaf 
extract has gained 
immense popularity due to its potent therapeutic value and is 
now available as dietary supplement and marketed as a 
nutraceutical product. The nutrients in 
papaya leaf
	Inhibition efficiency (%)
_
_____________________________________________
_
Association
 
Zn
2+ (50 ppm) 
day
 
 
4 9.2 
 
28% 65% 
 
efficiency: From 
 
of CPL (2 ml) and 
corrosion
 inhibition efficiency, for up to three days. 
After
to74%. The results are clearly 
entered
Table-
4
Effect of Immersion time on IE
 
Zn2+ (50 
ppm)
Inhibitor system 
2ml CPL extract + 50 ppm Zn
2+
 
Immersion Time: One day Figure-3 
Influence
 of P on Inhibition efficiency Figure-4 
of
 immersion period on Inhibition efficiency (%)
extract has gained 
immense popularity due to its potent therapeutic value and is 
now available as dietary supplement and marketed as a 
papaya leaf
 extract 
include the minerals, magnesium, potassi
acids and vitamins A, C, and B. Papaya leaves contains major 
phyto chemicals such as an alkaloid of Carpaine, Malic acid, 
Immersion days
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After
 7 days the IE is decreased 
entered
 in table 4. 
4
 
 
of the CPL extract (2ml) -
ppm)
  IE%
No. of days of immersion 
1 Day 3 Days 7 Days 
91% 80% 74% 
 
include the minerals, magnesium, potassi
um, iron, most amino 
acids and vitamins A, C, and B. Papaya leaves contains major 
phyto chemicals such as an alkaloid of Carpaine, Malic acid, 
\n\r\n\n


	
ResearchJournalofChemicalSciences___________________________________________________________ISSN2231-606XVol. 4(8), 88-93,August (2014) Res.J.Chem.Sci.   International Science Congress Association 
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quinic acid, a phenolic compound such as manghaslin as a anti-oxidant and also the papaya proteinase of papain.  FTIR spectra [KBr] of C.Papaya leaves and the thin film formed on the mild steel immersed in 60ppm Cl solution with 50ppm Zn2+ ion in the presence of the inhibitor formulations are shown in figure 5a and 5b.  Figure-5a Powdered C.Papaya leaves Figure-5b Thin film formed on the mild steelThe –OH stretching in phenol has decreased from 3239cm-1 to 3238cm-1, the -C-O strectching frequency has decreased from1235cm-1 to 1222cm-1, the carboxylic acid –OH stretchin frequency has decreased from 2921 to 2913cm-1, the carbonyl group in amide has shifted from 1740to 1744cm-1, the NH stretching frequency has decreased from 3489 to 3445cm-1, the aromatic C-N stretching frequency has shifted from 1366 to 1370cm-1. The peak at 1626cm-1 is of carbonyl group(C=Ostrectching) and ether groups (-O-stretching ) peak appeared at 1041cm-1 (figure-5a )were due to the presence of carboxy methy cellulose of papaya. These bands are vanished from the Figure b, which is due to the interaction between the functional group and the metal. Thus these bands were clearly proved the complex of CPL extract - Zn2+ which is formed on the metal surface as a protective coating. Conclusion The present study leads to the following conclusions: i. The formulations of 2ml CPL extract and 50ppm of Zn2+ provide 91% inhibition efficiency to mild steel immersed in aqueous medium containing 60ppm of Cl ion. ii. Synergistic effect exists between CPL extract and Zn2+. iii. The IE decreases, when the period of immersion increases. iv. As the value of pH is increased the corrosion inhibition efficiency also increased. v. FTIR spectra reveal that he protective film consists of Fe3+ - C. Papaya extract complex References 1.Quarishi M.A., Yadav D.K. and Ahamad I., Green approach to corrosion inhibition by black pepper extract in hydrochloric acid solution, Open corrosion journal, , 56-60, (2009)
2.Vasudha V.G. and Shanmuga Priya K., Polyalthia 
Longifolia as a corrosion inhibitor for mild steel in HCl 
solution, Res. J. Chem. Sci.,3(1),21-26(2013)  3.Ananth kumar S., Sankar A., Ramesh kumar S., Oxystelma Esculentum leaves extracts as corrosion inhibitor for mild steel in acid medium, International journal of Scientific and Technology Research, 2(9), (2013) 
4.Saxena Dinesh, Dwivedi Vivek and Mishra Pankaj Kumar, 
Inhibition of Corrosion of Carbon Steel in Sea Water by an 
Aqueous Extract of Eclipta alba Leaves – Zn2+ system, 
Res. J. Chem. Sci.,3(2), 16-19 (2013)5.Hemalatha J., Sankar A., Ananth kumar S., Ramesh kumar S., Nelumbo nucifera flower extract as mild steel corrosion inhibitor in 1N HSO medium, Int. J. Computer Engg.& sci.,3(1), 15-20, (2013)
6.James A.O. and Akaranta O., Inhibition of Corrosion of 
Zinc in Hydrochloric Acid Solution by Red Onion Skin 
Acetone Extract, Res.J.chem.sci.,1(1), 31-37 (2011)7.Hussin M.H. and Kassim M.J., Electro chemical studies of mild steel corrosion inhibition in aqueous solution by Uncariagambir extract, Journal of Physical Science, 2(1), 1-13, (2010)8.Alinnor I.J., Ejikeme P.M., Corrosion inhibition ofAluminium in acidic medium by different extracts ofOcimum gratissimum, American Chemical Science Journal, 2(14), 122-135, (2012)9.http://www.herbalist.com/wiki.details/93/category/11/,2011/08/17-papaya leaf (2014)
400
600
800
1000
1200
1400
1600
1800
2000
2400
2800
3200
3600
4000
1/cm
88
90
92
94
96
98
100
102
104
%T
3890.59
3537.60
3445.01
3275.27
3238.62
3158.57
3125.78
2913.60
2355.19
2306.00
1744.69
1519.97
1370.48
1222.92
550.70
438.82
Metal I
400
600
800
1000
1200
1400
1600
1800
2000
2400
2800
3200
3600
4000
1/cm
86
88
90
92
94
96
98
100
102
%T
3729.53
3489.38
3278.16
3239.59
3077.56
2921.32
2853.81
2685.03
2353.26
2309.86
1626.06
1545.05
1366.62
1314.54
1235.46
1041.61
935.52
891.15
771.56
677.04
660.65
608.57
591.21
552.63
542.02
Powder Inh
ResearchJournalofChemicalSciences___________________________________________________________ISSN2231-606XVol. 4(8), 88-93,August (2014) Res.J.Chem.Sci.   International Science Congress Association 
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10.Okafor P.C., Ebenso E.E., nhibitive action of Carica papaya extracts on the corrosion of mild steel in acidic media and their adsorption characteristics, Pigment and Technology, 36(3), 134-140, (2007)11.Ebenso E.E., Ibok U.J., Ekpe U.J., Umoren S., Jackson E., Abiola O.K., Oforka N.C. and Maritinez S., Corrosion inhibition studies of some plant extracts on aluminium in acidic medium, Transactions of the SAEST (Society for Advancement of Electrochemical Science and Technology), 39(4), 117-123, (2004)12. Ebenso E.E., Udofot J.J., Ekpelbok U.J., Studies on the inhibition of mild steel corrosion by some plant extracts in acidic medium, Discovery and Innovation, 10(1-2), 52-59, (1992)13.Loto C.A., Loto R.T. and Popoola A.P.I., Inhibition effect of extracts of Carica Papaya and Camellia Sinensis leaves on the corrosion of Duplex ( ) Brass in 1M nitric acid, Int. J. Electrochem. Sci.,l.6, 4900-4914, (2011)14.Sangeetha M., Rajendran S., Sathiyabama J. and P. Prabhakar P., Eco friendly extract of Banana peel as corrosion inhibitor for carbon steel in sea water, J. Nat. Prod. Plant. Resour., 2(5), 601-610, (2012)15.Sribharathy V., Susai Rajendran and Sathiyabama J.,Inhibitory action of Phyllanthus Amarus extracts on the corrosion of mild steel in sea water, Chem. Sci Trans.,. 2(1), 315-321, (2013)16.Arockia Selvi J., Susai Rajendran, Ganga Sri V., John Amalraj A., Narayanasamy B., Corrosion inhibition by Beet root extract, Portugaliae Electrochimica Acta, 27( 1),1-11, (2009)17.Balanaga karthik B., Selvakumar P., Thangavelu C., Inhibition of carbon steel corrosion by DTPMP-SPT-Zn2+system, International Journal of Scientific and Research Publications, 4(2), (2014)  18.Prabhakaran M., Ramesh S. and Periyasamy V., Synergistic effect of Thiomalic acid and Zinc ions in corrosion control of carbon steel in aqueous solution, Research Journal of Chemical Sciences, 4(1), 41-49,(2014)19.Appa Rao B.V. and Srinivasa Rao S., Synergistic inhibition of corrosion of carbon steel by ternary formulations containing phosphate, Zn(II) and ascorbic acid, Research journal of recent sciences, (ISC-2011), 93-98, (2012)20.Thangavelu C., Umarani M., Patric Raymond P. and Sekar M., Eco-friendly inhibitor system for corrosion inhibition of carbon steel in high chloride media, Rasayan J.Chem.,4(2), 245-250, (2011)
21. Rajendran S., Shanmugapriya S., Rajalakshmi T. and
Amal Raj A.J., Corrosion Inhibition by an Aqueous 
Extract of Rhizome Powder, Corrosion,61(7), 685-692, 
(2005)22.Olafsdottir, Elin S., Bolt Jorgensen, Lise, jaroszewski, Jerzy W., Cyanogenesis glucosinolate-producing plants: Carica papaya and Carica quercifolia, Phytochemistry,60(3), 269-273, (2002) 
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