缓蚀剂在铜表面吸附行为的研究  被引量:10

Adsorption behavior of inhibitor on copper surface

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作  者:刘娜娜[1] 孙建林[1] 夏垒[1] 曾颖峰[2] 

机构地区:[1]北京科技大学材料科学与工程学院,北京100083 [2]中国石化石油化工科学研究院,北京100083

出  处:《物理学报》2013年第20期149-154,共6页Acta Physica Sinica

基  金:国家科技支撑计划重点项目(批准号:2011BAE23B00);国家自然科学基金(批准号:51274037)资助的课题~~

摘  要:采用密度泛函理论计算了缓蚀分子苯并三氮唑(BTA)和二巯基噻二唑(DMTD)的全局反应活性和局部反应活性.采用分子动力学方法模拟了不同含量的BTA和DMTD对其热力学性质的影响.同时通过腐蚀试验研究了缓蚀剂复配体系的缓蚀效果.结果表明:两种缓蚀分子的缓蚀效率关系为BTA小于DMTD,活性主要集中于N和S原子上,有多个活性位点,因此,缓蚀剂分子平卧式吸附在铜表面;铜表面吸附单个缓蚀剂分子BTA和DMTD后,室温下比热容基本相同,但随缓蚀剂含量的增加,比热容呈增大趋势.这为铜箔轧制油缓蚀剂的选择提供理论指导.通过腐蚀试验研究,复配体系缓蚀具有很好的缓蚀效果,BTA和DMTD的复配比例为1:1时最佳.The global and local activity of benzotrialole (BTA) and 2,5-Dimercapto-1,3,4-thiadiazole (DMTD) are calculated by density function theory. Thermodynamic properties of BTA and DMTD are simulated by molecular dynamics. The corrosion inhibition effect of mixed system inhibitor is studied through corrosion test. The results show that the inhibition efficiency of DMTD is larger than that of BTA. There are several active sites which focus on N and S atoms. So the inhibitors are absorbed on the surface of Cu in the parallel direction. The specific heat capacities of Cu absorbing inhibitor are the same as those without Cu adsorbing inhibitor at room temperature. The specific heat capacities increase with inhibitor increasing. They provide the reference for the selection of the inhibitor. The effect of mixed system inhibitor is better and the best mixed ratio is BTA:DMTD=1:1.

关 键 词:密度泛函理论 分子动力学方法 反应活性 热力学性质 

分 类 号:TG174.42[金属学及工艺—金属表面处理]

 

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