Electrochemical behavior of Mg-Al-Pb alloy in 3.5% NaCl solution

被引：1

作者：

文利 ^{[1
,2
]}

余琨 ^{[1
,2
]}

房洪杰 ^{[1
]}

熊汉青 ^{[1
,2
]}

尹翔 ^{[2
]}

朱化龙 ^{[1
]}

马家骥 ^{[1
]}

姜大越 ^{[1
]}

机构：

[1] Department of Materials Science and Engineering, Yantai Nanshan University

[2] School of Materials Science and Engineering, Central South University

来源：

Journal of Central South University | 2016年 / 23卷 / 10期

关键词：

Mg-Al-Pb alloy; electrochemical behavior; corrosion; solid solution; as-aged state;

D O I：

暂无

中图分类号：

TG178 [各种金属及合金的腐蚀、防腐与表面处理];

学科分类号：

080503 ;

摘要：

An investigation on electrochemical behavior of Mg-5%Pb alloy, Mg-6%Al alloy and Mg-6%Al-5%Pb alloy（mass fraction） in 3.5% Na Cl（mass fraction） solution was conducted using electrochemical measurements and corroded morphology observation, in which solid solution and the as-aged state of each alloy were compared to discuss the influence mechanism of lead and aluminium on the electrochemical properties of alloys. The X-ray diffraction（XRD） analysis was performed to make microstructure characterization. The electrochemical results indicate that the corrosion of Mg-5%Pb alloy is predominated by homogeneous pitting and dissolution of PbCl2 film due to Cl ions attack, while corrosion crevice propagates along grain boundaries in solid solution of Mg-6%Al alloy and the micro galvanic corrosion also plays vital role in Mg17Al12 phase containing experimental alloys. The co-existence of lead and aluminium in magnesium alloy increases corrosion current density and electrochemical activity as well. The comparison between solid solution and the as-aged state demonstrates that Mg2 Pb and Mg17Al12 somewhat increase corrosion resistance but lighten anodic polarization by facilitating corrosion product flaking off.

引用

页码：2475 / 2482

页数：8

共 23 条

[1] Corrosion behavior of Mg-Al-Pb and Mg-Al-Pb-Zn-Mn alloys in 3.5% NaCl solution [J].

王乃光 ;

王日初 ;

彭超群 ;

冯艳 ;

张翔宇 .

Transactions of Nonferrous Metals Society of China, 2010, 20 (10) :1936-1943

[2]

Influence of aluminium and lead on activation of magnesium as anode[J]. 王乃光,王日初,彭超群,冯艳,张翔宇.Transactions of Nonferrous Metals Society of China. 2010(08)

[3]

Enhancement of the discharge performance of AP65 magnesium alloy anodes by hot extrusion[J] . Naiguang Wang,Richu Wang,Chaoqun Peng,Yan Feng.Corrosion Science . 2013

[4]

Nucleation mechanism of Mg 17 Al 12 -precipitates in binary Mg–7＜ce:hsp sp="0.25"/＞wt.% Al alloy[J] . M. Lalpoor,J.S. Dzwonczyk,N. Hort,S.E. Offerman.Journal of Alloys and Compounds . 2013

[5]

EIS evaluation of steady-state characteristic of 316L stainless steel passive film grown in acidic solution[J] . C. Boissy,C. Alemany-Dumont,B. Normand.Electrochemistry Communications . 2013

[6]

Effect of hot rolling and subsequent annealing on electrochemical discharge behavior of AP65 magnesium alloy as anode for seawater activated battery[J] . Naiguang Wang,Richu Wang,Chaoqun Peng,Yan Feng,Bin Chen.Corrosion Science . 2012

[7]

A study on the mechanical and corrosion properties of lead added magnesium alloys[J] . Materials and Design . 2012

[8]

Electrochemical behaviour of AZ61 magnesium alloy in dilute NaCl solutions[J] . Lei Wang,Tadashi Shinohara,Bo-Ping Zhang.Materials and Design . 2011

[9]

Effects of zirconium addition on as-cast microstructure and mechanical properties of Mg–3Sn–2Ca magnesium alloy[J] . Mingbo Yang,Xiaofeng Liang,Zhu Yi,Fusheng Pan.Materials and Design . 2010 (4)

[10] Effect of tin modification on corrosion of AM70 magnesium alloy [J].

Song, Guang-Ling .

CORROSION SCIENCE, 2009, 51 (09) :2063-2070

← 1 2 3 →