Research Journal of Chemical Sciences ___ ______________________________ ______ ____ ___ ISSN 22 31 - 606X Vol. 5 ( 1 1 ), 59 - 6 6 , November (201 5 ) Res. J. Chem. Sci. International Science Congress Association 59 Azadirachta Indica Extract as corrosion Inhibitor for Copper in Nitric Acid Medium Patel K.K. and Vashi R.T.* Chemistry Department, Navyug Science College, Surat, Gujarat, 395009, INDIA Available online at: www.isca.in , www.isca.me Received 7 th August 201 5 , revised 8 th October 201 5 , accepted 7 th November 201 5 Abstract Azadirachta Indica ( AI ) leaves extract was investigated as a copper corrosion inhibitor in nitric acid. Corrosion rate and inhibition properties were studied by using weight - loss, effect of temperature, polarization and electrochemical impedance spectroscopic methods. Corrosion rate increases with the increase in acid concentration and temperature. The percentage of inhibition efficiency (I.E.) increases with increase AI concentration. The value of free energy of adsorption ( ∆G a ) and heat of adsorption (Q ads ) obtained were negative. The inhibition e ffect is discussed in view of AI molecules adsorbed on the metal surface and it follows Langmuir adsorption isotherm. Polarization curve indicates that inhibitor act as mixed type (anodic and cathodic) and the inhibition efficiency was found up to 98%. It was found that AI extract is good inhibitor for the corrosion of copper in nitric acid medium. Keywords: Copper, corrosion, inhibitor, azadirachta indica ( AI ) leaves extract . Introduction Corrosion of metal/alloy, which can be defined as the deterioration of materials due to their reaction with the environment. Copper is a metal having a wide range of applications due to its good properties. It is used in electronics, for production of wires, sheets, and tubes, and also to form differen t alloys; its corrosion resistance becomes less while the aggressive solution concentration increases 1,2 . Copper corrosion in nitric acid solution induced a great deal of research 3,4 . It is noticed that presence of heteroatom in organic compound such as ni trogen 5,6 , oxygen 7,8 , phosphorus 9 and sulphur 10,11 molecules are good corrosion inhibitors, but these compounds are highly toxic. The purpose of the present work is to develop eco - friendly corrosion inhibitors having good inhibition efficiency at low ris k of environmental pollution 12 . From many decades researchers attracted to study plant extracts as eco - friendly inhibitors for metal corrosion. Green inhibitors are environment friendly, source of non - toxic compounds, bio - degradable and of potentially low cost inhibitors for preventing metal corrosion 13 . Most of the naturally occurring substances are safe and can be extracted by simple procedure. As a natural product they are safe and can be extracted by simple procedure. Azadirachta Indica (Neem) is more useful for its medicinal, chemical and biological activities. It is one of the richest sources of secondary metabolites in nature 14 . Natural products have been isolated from various parts of a tree 14 - 16 , many of them acts as insect antifeedant, antifungal, insect growth regulatory, antiviral and antimalarial properties 17,18 . The AI extract has been reported to effectively inhibit the metal corrosion in acidic medium 19 - 28 . The present study investigated the inhibition effect of AI leaves for copper corrosion in nitric acid solution by using weight loss, effect of temperature, potentiodynamic polarization and electrochemical impedance spectroscopic methods. Material and Methods Sample and Solution preparation: The copper metal used in this study with a chemical composition 99.99 % Cu and 0.01 % S. The copper specimens of the size 4.5  2  0.178 cm were used. The specimens were cleaned by washing with distilled water, degreased by acetone, washed once more with bidistilled water and finally dried and weighted by using electronic balance. The corrosive solution was prepared by diluting analytical grade of HNO 3 purchased from Merck using double distilled water. Preparation of extract: The AI leaves were dried, gro und to powder form and boiling with double distilled water to making extract of different concentrations 0.6, 0.8, 1.0 and 1.2 g/l. Mass loss measurements: For mass - loss experiment, the copper specimen having an area of 0.1988 dm 2 were each suspended and completely suspended in 230 ml of HNO 3 solution with and without different AI extract concentrations using glass hooks at 301 1 K for 24h. The coupons were retrieved after 24h, washed by distilled water, dried well and reweighed. From the weight loss dat a, Corrosion rate (CR) was calculated. Temperature effect: To study the temperature effect, the copper coupons were completely immersed in 230 ml of 1 M HNO 3 solution with and without different AI extract Research Journal of Chemical Sciences ___ ______________________________ ___________________ ____ ___ ISSN 22 31 - 606X Vol. 5 ( 1 1 ), 59 - 6 6 , November (201 5 ) Res. J. Chem. Sci. International Science Congress Association 60 concentrations using glass hooks and corrosion rat e were determined at 313, 323 and 333K for 2h to calculate inhibition efficiency, activation energy (Ea) and heat of adsorption (Q ads ). Potentiodynamic polarization measurements: For polarization study, metal specimens were immersed with and without AI ex tract in 0.5 M HNO 3 solution. In the electrochemical cell copper specimens as a working electrode, saturated calomel electrode as a reference electrode and platinum electrode as an auxiliary electrode and allowed to establish a steady - state open circuit po tential (OCP) for approximately 15 min. The polarization curves were plotted with current - potential. An anodic and cathodic polarization curve gives correspondently anodic and cathodic Tafel lines. The intersect point of Tafel lines gives the corrosion pot ential (E corr ) and corrosion current (i corr ) 29 . Electrochemical impedance spectroscopy measurements : EIS measurements were made at corrosion potentials over a frequency range of 0.1 Hz to 10 5 Hz by a sine wave with potential perturbation amplitude of 5 mV. The real Z and imaginary Z parts were measured at various frequencies. From the plot of Z Vs. Z, the charge transfer resistance (R ct ), and double layer capacitance (C dl ) were calculate d. An experiment was carried out both with and without inhibitor. Results a nd Discussion Weight loss experiments: The weight loss experiments for copper corrosion in different concentration (0.5, 0.75 and 1 M) of HNO 3 solution containing different AI concentration (0.6, 0.8, 1.0, 1.2 g/l) at 301  1 K for exposure period of 24h was investigated. Inhibition efficiency (I.E.) was calculated by following equation, I . E . ( % ) = ୛ ౫ ି ୛ ౟ ୛ ౫ 100 (1) Where : W u - Weight loss without inhibitor, W i - Weight loss with inhibitor. The surface coverage (θ) of the copper specimen for different inhibitor concentration in HNO 3 solution have been evaluated by weight loss experiments using following equation, θ = ୛ ౫ ି ୛ ౟ ୛ ౫ (2) From the results obtain fro m table - 1 shows that when acid concentration increase, corrosion rate increase and inhibition efficiency decrease. The results obtained were presented in table - 2 and in figure - 1, the corrosion rate of 0.5 M HNO 3 was decreased from 90.52 to 5.03 mg/dm 2 wh ile inhibition efficiency increases from 69.45 to 94.45 % with increase in inhibitor concentration from 0.6 - 1.2 g/l. It can be concluded that inhibition efficiency is directly proportional to the inhibitor concentration. Table - 1 Corrosion rate (CR) and inhibition efficiency (I.E.) for copper corrosion in different concentration of HNO 3 solution in the presence and absence of AI extract for 24h at 301 1 K. Inhibitor Concentration g/l Acid Concentration 0.5 M 0.75 M 1.0 M CR I. E. CR I. E. CR I. E. mg/dm 2 % mg/dm 2 % mg/dm 2 % Blank 90.52 - 281.55 - 1030.67 - 0.6 27.65 69.45 90.50 67.86 356.98 65.36 0.8 25.14 72.23 80.45 71.43 311.73 69.75 1.0 19.11 78.89 65.36 76.78 276.53 73.17 1.2 5.03 94.45 35.20 87.50 196.09 80.97 Research Journal of Chemical Sciences ___ ______________________________ ___________________ ____ ___ ISSN 22 31 - 606X Vol. 5 ( 1 1 ), 59 - 6 6 , November (201 5 ) Res. J. Chem. Sci. International Science Congress Association 61 Table - 2 Inhibition efficiency, corrosion rate and surface coverage of AI extract on Copper corrosion in 0.5 M Nitric acid for an immersion period of 24h at 301 1 K Inhibitor concentration g/l CR (ρ) mg/dm 2 log ρ I.E. % surface coverage θ 1 - θ log(θ/1 - θ) Blank 90.52 1.9567 - - - - 0.6 27.65 1.4417 69.45 0.6945 0.3055 0.3567 0.8 25.14 1.4004 72.23 0.7223 0.2777 0.4151 1.0 19.11 1.2813 78.89 0.7889 0.2111 0.5725 1.2 5.03 0.7016 94.45 0.9445 0.0555 1.2309 Figure - 1 Corrosion rate and Inhibition efficiency of copper corrosion in 0.5 M HNO 3 solution in presence of different concentration AI extract for an immersion period of 24h The surface coverage  value was calculated by using eq uation - 2. The plot of inhibitor concentration C inh ver sus C inh /θ is presented in figure - 2 gives straight line with almost unit slope indicate that the system follows Langmuir Adsorption Isotherm 30 . This isotherm can be represented as, େ ౟౤౞  = ଵ ୏ ౗ౚ౩ + c ୧୬୦ (3) Where, K ads is the equilibrium constant an d C inh is the inhibitor concentration. Linear plot obtained from figure - 2 shows that constituents of AI extract on a copper surface making a barrier for charge and mass transfer between the metal and environment follows Langmuir adsorption isotherm which shows inhibition efficiency. Temperature effect: The mass loss experiments were also carried out at different temperature 313, 323 and 333K in 1M HNO 3 to investigate the influence of temperature on the rate of corrosion for immersion period of 2h. The va lue of energy of activation (E a ) has been calculated with the help of Arrhenius equation 30 . log ρ మ ρ భ = ୉ ౗ ଶ . ଷ଴ଷ ୖ ቀ ଵ ୘ భ − ଵ ୘ మ ቁ (4) Where : ρ 1 and ρ 2 are the corrosion rate at temperature T 1 and T 2 respectively. As data given in table - 3, the values of E a a re higher in inhibited acid than uninhibited acid ranging from 65.15 78.94 kJmol - 1 , which indicates that the inhibitors are strongly adsorbed on metal surface. From the data of table - 3 and figure - 4, as temperature increases, rate of corrosion increase while percentage of inhibition efficiency decreases. 0 10 20 30 40 50 60 70 80 90 100 Blank 0.6 0.8 1 1.2 corrosion rate (mg/dm 2 ) Inhibitor concentration (g/l) 50 70 90 0.6 0.8 1 1.2 (%) I. E. Inhibitor concentration (g/l) Research Journal of Chemical Sciences ___ ______________________________ ___________________ ____ ___ ISSN 22 31 - 606X Vol. 5 ( 1 1 ), 59 - 6 6 , November (201 5 ) Res. J. Chem. Sci. International Science Congress Association 62 Figure - 2 Langmuir adsorption isotherm for copper corrosion in 0.5 M HNO 3 solution at different concentration of AI extract Table - 3 Temperature effect on corrosion rate (CR), activation energy (Ea) and heat of adsorption ( Q ads ) for copper in 1 M HNO 3 in absence ant presence of AI extract for an immersion period of 2h AI Concentration g/l Temperature Mean (Ea) from Eq. (1) kJ mol - 1 Q ads kJ mol - 1 313 K 323 K 333 K CR I. E. CR I. E. CR I. E. 313 - 323 K 323 - 333K mg/dm 2 % mg/dm 2 % mg/dm 2 % Blank 442.46 - 754.19 - 1960.88 - 65.15 - - 0.6 110.61 75.00 191.06 74.67 593.29 69.74 73.65 - 1.47 - 22.02 0.8 95.53 78.41 170.95 77.33 492.73 74.87 71.80 - 5.27 - 12.11 1.0 75.42 82.95 140.78 81.33 432.40 77.95 76.42 - 9.29 - 18.68 1.2 55.31 87.50 110.61 85.33 336.87 82.82 78.94 - 15.57 - 16.80 Figure - 3 Arrhenius plot for copper corrosion in 1 M HNO 3 in absence and presence of the different concentration of AI extract 0.5 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.4 0.6 0.8 1 1.2 Cinh / θ Cinh (g/l) 1 1.5 2 2.5 3 3.5 4 3 3.1 3.20 log ρ ( corrosion rate,mg/dm 2 ) 1/T x 1000 K 0.6 g/l 0.8 g/l 1.0 g/l 1.2 g/l Blank Research Journal of Chemical Sciences ___ ______________________________ ___________________ ____ ___ ISSN 22 31 - 606X Vol. 5 ( 1 1 ), 59 - 6 6 , November (201 5 ) Res. J. Chem. Sci. International Science Congress Association 63 The values of heat of adsorption (Q ads ) were calculated by following equation 31 . Q ୟୢୱ = 2 . 303 R ቂ log ቀ θ మ ଵ ି θ మ ቁ − log ቀ θ భ ଵ ି θ భ ቁ ቃ  ቂ ୘ భ ୘ మ ୘ మ ି ୘ భ ቃ (5) Where,  1 and  2 (  =W u  W i / W u ) are the fraction of the metal surface covered by the inhibitors at temperature T 1 and T 2 respectively. The negative and lower values of Q ads support higher Inhibition efficiency achieved by spontaneous adso rption of the inhibitor. Potentiodynamic polarization study: Figure - 5 represents the Potentiodynamic polarization curves of copper in 0.5 M HNO 3 in the presence and absence of AI extract. Associated electrochemical parameters such as corrosion potential (E corr ), corrosion current density (i corr ), anodic Tafel slope( β a ) , cathodic Tafel slope (β c ) and percentage inhibition efficiency (I.E.) are given in table - 4. From figure - 5 and table - 4, it was observed that the addition of AI extract in acid solution indicates the significant decrease in the corrosion current density (i corr ) and decrease in the corrosion rate with respect to the blank. There is significant change in the anodic and cathodic slopes after the addition of the inhi bitor. This Tafel curves indicate that AI function as a mixed - type inhibitor. Inhibition efficiency (I.E.) was calculated using following equation. I . E . ( % ) = ୧ ౙ౥౨౨ ି ୧ ౙ౥౨౨ ( ౟౤౞ ) ୧ ౙ౥౨౨ 100 (6) Electrochemical impedance spectroscopy (EIS) measurements: Nyqui st plots for the corrosion of copper in 0.5 M HNO 3 solution in the presence and absence of AI extract was examined by EIS method at room temperature was shown in figure - 6 and table - 5. It is observed from figure - 6 that the impedance diagram is almost semici rcular in appearance, but not perfect semicircle. The difference has been att ributed to frequency dispersion . The semicircular nature of the plots indicates that the corrosion of copper is mainly controlled by charge transfer process. The diameter of capa citive loop in the presence of inhibitor is bigger than that in the absence of inhibitor. The high frequency capacitive loop is related to the charge transfer resistance (R ct ). To calculate the double layer capacitance (C dl ), the frequency at which the im aginary component of the impedance is maximum was found as presented in the following equation 32 . C ୢ୪ = ଵ ଶ π ୊ ౣ౗౮ ୖ ౙ౪ (7) Where f is the frequency at the maximum height of the semicircle on the imaginary axis and R ct is the charge transfer resistance 33 . Inhibition efficiency was calculated using following equation. I . E . ( % ) = େ ౚౢ ି େ ౚౢ ( ౟౤౞ ) େ ౚౢ 100 (8) The addition of inhibitor increase R ct value while decreases in C dl values which is due to the adsorption of inhibitor on the metal surface. The results su ggest that the inhibitor acts by the formation of a protective layer on the surface, which modifies the metal/solution interface. The result indicates that AI leaves extract performs as good inhibitor for the corrosion of copper in nitric acid media. Eddy and Ebenso 34 noted that AI leaves extract contains saponin, tannin, alkaloid, glycoside, anthraquinone and flavanoid as major phytochemical constituents. The results indicate that AI leaves extract performs as good inhibitor for the corrosion of copper in nitric acid solution. Figure - 4 Effect of temperature on inhibition efficiency for copper corrosion in 1 M HNO 3 at different concentration of AI extract for immersion period of 2h 60 65 70 75 80 85 90 95 100 313 323 333 Inhibition Efficiency (%) Temperature K 0.6 g/l 0.8 g/l 1.0 g/l 1.2 g/l Research Journal of Chemical Sciences ___ ______________________________ ___________________ ____ ___ ISSN 22 31 - 606X Vol. 5 ( 1 1 ), 59 - 6 6 , November (201 5 ) Res. J. Chem. Sci. International Science Congress Association 64 Figure - 5 Potentiodynamic polarization plots for copper in (a) 0.5 M HNO 3 and (b) 0.5 M HNO 3 in the presence of 1.2 g/l AI extract Figure - 6 Nyquist plot for copper in (a) 0.5 M HNO 3 and (b) 0.5 M HNO 3 in the presence of 1.2 g/l AI extract Table - 4 Potentiodynamic polarization parameters of copper in 0.5 M HNO 3 and in presence of 1.2 g/l AI extract System E corr V I corr (μA/cm 2 ) Tafel Slope Inhibition efficiency (I.E. %) Anodic +β a Cathodic - β c β (mV) By Polarization Method By Weight loss Method A - 0.028 2.062 5.887 2.327 0.7251 - - B - 0.035 0.040 15.011 6.783 1.16636 98.06 94.45 A= 0.5 M HN O 3 B= 0.5 M HN O 3 + 1.2 g/l AI extract Research Journal of Chemical Sciences ___ ______________________________ ___________________ ____ ___ ISSN 22 31 - 606X Vol. 5 ( 1 1 ), 59 - 6 6 , November (201 5 ) Res. J. Chem. Sci. International Science Congress Association 65 Table - 5 EIS parameters for the corrosion of copper in 0.5 M HNO 3 containing AI extract System R ct (Ω cm 2 ) C dl (μFcm 2 ) I.E. (%) By EIS method By Weight loss method A 85 53.52 - - B 970 0.53 99.00 94.45 Table - 6 The phytochemical constituents of leaves extract of Azadirachta indica 34 Phytochemicals Leaves +++ = present in large quantity ++ = moderately present + = present in trace quantity Flavanoid + Anthraquinone + Phlobatanin ++ Cardiac glycosides +++ Tannin +++ Terpene +++ Alkaloid +++ Saponin +++ Conclusion AI was found to be a good eco - friendly inhibitor for the corrosion control of copper in HNO 3 solution. The inhibition efficiency increase with increase in AI concentration. AI adsorbed on metal surface follows Langmuir adsorption isotherm. Tafel plot indicat es AI acts as a mixed type inhibitor. AC impedance spectra reveal that a protective film is formed on the metal surface. 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