Polyaspartic acid as a corrosion inhibitor for WE43 magnesium alloy

2015-02-16 00:55
Journal of Magnesium and Alloys 2015年1期

Institute of Oceanology,Chinese Academy of Sciences,Qingdao,266071,China

Polyaspartic acid as a corrosion inhibitor for WE43 magnesium alloy

Lihui Yang*,Yantao Li,Bei Qian,Baorong Hou

Institute of Oceanology,Chinese Academy of Sciences,Qingdao,266071,China

The inhibition behavior of polyaspartic acid(PASP)as an environment-friendly corrosion inhibitor for WE43 magnesium alloy was investigated in 3.5 wt.%NaCl solution by means for EIS measurement,potentiodynamic polarization curve,and scanning electron microscopy. The results show that PASP can inhibit the corrosion of WE43 magnesium alloy.The maximum inhibition effciency is achieved when PASP concentration is 400 ppm in this study.

Magnesium alloy;Polyaspartic acid;Inhibitor;Corrosion

1.Introduction

Magnesium alloys have recently attracted more and more attention for their unique physical and chemical properties, including light weight,high strength-to-weight ratio,excellent damping behavior,good electromagnetic shielding,satisfactory castalility,and wonderful recyclability[1-6].However, magnesium alloys have some undesirable properties,such as the high chemical reactivity and poor corrosion resistance that have hindered their use in many applications[7].

Inhibitor is one of the most practical corrosion protection methods for protecting metals and alloys from corrosion attack.Corrosion inhibitors have been extensively studied on steel,aluminum alloys,and coppersubstrates[8-13]. Recently there are also a few publications about directly using corrosion inhibitors in solution to protect magnesium alloys [14-20].However,the main challenge is the lack of high effciency inhibitors.Also many corrosion inhibitors have some health and/or environmental problems due to their toxicity.It is highly desired that new inhibitors for Mg are non-toxic and environment-friendly.

PASP has been synthesized and used as one of the green water treatment agents[21,22].There are several researches on the inhibition of PASP for carbon steel[9].However,there are few reports on the corrosion inhibition behavior of PASP on magnesium alloys in sodium chloride solutions.

In the present work,the inhibition behavior of PASP as an environment-friendly corrosion inhibitor for WE43 magnesium alloy was investigated.EIS measurement,Potentiodynamic polarization and SEM were employed to study the effect of different concentration of PASP.

2.Experimental

2.1.Material and solution

The substrate material used was WE43 alloy(4 wt.%Y, 3 wt.%Nd,0.5%Zrand Mg balance)with a size of 10 mm×10 mm×3 mm.Specimens were abraded with 2000#SiC paper to obtain an even surface,ultrasonically cleaned using acetone and washed with an alkaline detergent.

The chemical structure of the used polyaspartic acid (PASP)is shown in Fig.1.PASP was prepared by thermal condensation reaction ofL-aspartic acid.The synthesized PASP was characterized by Fourier transform infrared(FTIR). FTIR spectroscopy was performed using the Bruker Vertex 70 FT-IR.Spectra were collected from 16 scans at a resolution of 4 cm-1between 400 cm-1and 4000 cm-1.

2.2.Electrochemical measurements

To evaluatethecorrosion performance and possible behavior of the samples,electrochemical measurements were performed on an electrochemical analyzer(IM6ex,Zahner, Germany).Potentiodynamic polarization was conducted in neutral 3.5 wt.%NaCl aqueous solution at room temperature. A standard three-compartment cell was used with a saturated calomel electrode(SCE)and a platinum electrode as a reference and counter electrode,respectively.All of the electrodes were cleaned in acetone agitated ultrasonically,rinsed in deionized water before the electrochemical tests.The coated samples were masked with epoxy resins so that only 1 cm2area was exposed to the electrolyte.During the potentiodynamic sweep experiments,the samples were frst immersed into electrolyte for 10 min to stabilize the OCP.The sweeping rate was 1 mV/s for all measurements.Eletrochemical impedance spectroscopy(EIS)was performed in frequency range from 10 kHz to 10 mHZ.The obtained EIS data points were ftted using commercial software ZsimpWin.

2.3.SEM

Surface morphologies of the magnesium samples were observed by SEM(JSM-6480A,Japan Electronics)instrument before and after the immersion of samples in both the inhibited and the blank acid solutions.

3.Results and discussion

3.1.FTIR of PASP

Fig.2 shows the FTIR spectra of the synthesized PASP.The absorption bands appear at 1190 cm-1and 3411 cm-1correspond to the C-O and O-H,which is the major band of -COOH.Peak at 1390 cm-1is related to the C-N stretching mode of the acylamide group.The peak at 1600 cm-1is assigned to the bending of N-H.The results indicate that the PASP is successfully synthesized.

3.2.Eletrochemical impedance spectroscopy(EIS) measurements

Fig.3 shows the EISs of WE43 magnesium alloy in the blank and PASP containing solutions at room temperature. Two electrochemical equivalent circuits shown in Fig.4 are used to ft the different EIS plots.Fig.4a shows the circuit for an uninhibited WE43 magnesium alloy surface,and Fig.4b shows a circuit which simulates a WE43 magnesium surface with inhibitor deposits blocking the active corrosion sites.Rs represents the solution resistance;CPE1is the constant phase element related to the surface flm formed on WE43;Rfis the resistance of the protective-flm;CPE2is also a constant phase element representing the double layer capacitance of the metal/solution interface and Rctis the charge transfer resistance of the interface.L is the inductance,and W is the spreading resistance.The parameters derived from EIS curve ftting are listed in Table 1.

The polarization resistance,Rp=Rf+Rct,can be used to evaluate the inhibition effciency:

3.3.Potentiodynamic polarization curve tests

Fig.5 shows the polarization curves of samples in different concentrations of PASP solutions.It can be seen that for the WE43 Mg substrate,both cathodic and anodic branches exhibit anactiveresponsewhichsuggestingapoorcorrosionresistance. For samples,in different concentrations of PASP solution,the corrosion potential shifts towards the noble direction and the corrosion current density decreased.This indicates the increase of the corrosion resistance.However,with the presence of the passivation region,Tafel slopes are not clear in Fig.5 and Tafelmethodisnotfttoanalyze thepolarization curves.However,as acomplementtotheEIStests,thepolarizationtestsconfrmthat PASP could act as a good corrosion inhibitor for protecting WE43 magnesium alloy from corrosion.

Fig.1.Chemical structure of PASP repeat unit.

Fig.3.EISs of WE43 in 3.5%NaCl solution without or with PASP(a)blank;(b)with different concentration PASP(1-5):400 ppm;600 ppm;800 ppm;1200 ppm; 2000 ppm.

3.4.Morphological studies

Fig.6 shows the surface morphology of the WE43 Mg alloy samples after 3 days of immersion in 3.5 wt.%NaCl blank solution and that with various PASP concentrations.As shown in Fig.6(a),themetalsurfacewascoveredwithcorrosionproducts. WhenthePASPisaddedinthesolution,thereisaprotectiveflm formed by adsorption of PASP on the metal surface.Nonpenetrating cracked morphology with leaf-like microstructure existedontheseflms,whichisverysimilarwiththatofchemical conversioncoatings[23].TheflmisthemostcompactwhenthePASPconcentrationis400ppm.Theprotectivenatureoftheflm formed on the WE43 magnesium alloy is confrmed by both SEM examination and electrochemical methods.

Fig.4.Equivalent circuit for WE43 magnesium alloy in 3.5 wt.%NaCl solutions without and with PASP.

Table 1Inhibition effciencies based on EIS measurements and electrochemical parameters obtained from the measured EISs of WE43 magnesium alloy in 3.5 wt.%NaCl blank solution and PASP containing solutions.

Fig.5.Potentiodynamic polarization curves for WE43 alloy in the blank solution and PASP containing solution at 25°C(a)blank;(b-f)with different concentration PASP:400 ppm;600 ppm;800 ppm;1200 ppm;2000 ppm.

Fig.7.XRD patterns of WE43 magnesium alloy before(a)and after PASP solutions immersed(b).

Fig.6.SEM images of WE43 magnesium alloy after 3 days of immersion in 3.5 wt.%NaCl blank solution(a),and that with various PASP concentrations:b-400 ppm;c-600 ppm;d-800 ppm;e-1200 ppm and f-2000 ppm.

3.5.Inhibition mechanism

Fig.7 shows the XRD patterns of WE43 magnesium alloy before(a)and after PASP solutions immersed.It is noted that therearesomenew peaksappeared corresponding to Mg(OH)2.There maybe some other compositions which cannot be detected by XRD.We suppose that When PASP is added to the NaCl solution,PASP anions get into some relatively large pores of the Mg(OH)2surface flm,and chelate directly with the Mg2+ions dissolved from the substrate Mg alloy in the flm pores,forming PASP-Mg complex precipitated in the pores.The deposited PASP-Mg complex products seal the flm pores to a great degree.The best corrosion protection is offered by a surface flm with Mg(OH)2and PASPMg mixed at a certain ratio.

4.Conclusions

PASP was synthesized by a simple thermal condensation reaction method starting from L-aspartic acid and was confrmed by FTIR analysis to detect the existence of characteristic functional groups.

PASP has presented a good inhibitory action and a significant effciency for decreasing the corrosion rate of the studied magnesium alloys.The inhibition effciency was found to increase by increasing the PASP concentration;the best performance effciency of PASP on WE43 magnesium alloy was 94.2%,which took place in 400 ppm concentration.Potentiodynamic polarization results revealed that in different concentrations of PASP solution the corrosion potential shifts towards the noble direction and the corrosion current density decreased,which indicates the increase of the corrosion resistance.SEM displays that there are protective flms formed on the surface in different concentrations of PASP solution.

Acknowledgment

The authors gratefully acknowledge the fnancial support of the National Natural Science Foundation of China(No. 41276074)and National Basic Research Program of China (No.2014CB643304).

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Received 19 September 2014;revised 20 December 2014;accepted 25 December 2014 Available online 24 March 2015

*Corresponding author.

E-mail address:ylhheu@163.com(L.Yang).

Peer review under responsibility of National Engineering Research Center for Magnesium Alloys of China,Chongqing University.

http://dx.doi.org/10.1016/j.jma.2014.12.009.

2213-9567/Copyright 2015,National Engineering Research Center for Magnesium Alloys of China,Chongqing University.Production and hosting by Elsevier B.V.All rights reserved.

Copyright 2015,National Engineering Research Center for Magnesium Alloys of China,Chongqing University.Production and hosting by Elsevier B.V.All rights reserved.