X射线光电子能谱
咪唑
吡啶
吸附
化学
扫描电子显微镜
腐蚀
材料科学
无机化学
物理化学
化学工程
有机化学
复合材料
工程类
作者
Yuhao Song,Pengjie Wang,Zijie Tang,Zhonghui Li,K.R. Ansari,Mohd Talha,Ambrish Singh,Yuanhua Lin
标识
DOI:10.1177/1478422x251350823
摘要
This study aims to clarify the influence mechanism of pyridine ring substitution position on the performance of imidazolinyl pyridine-based preservatives, linking molecular structure with anti-corrosion performance. Two preservatives, MB2 and MB4, were designed. Their anti-corrosion performance and mechanism in 1 mol/L HCl were investigated via weight loss method, electrochemical tests, surface analysis: scanning electron microscope (SEM), energy dispersive X-ray spectroscopy (EDS), X-ray photoelectron spectroscopy (XPS) and theoretical calculations. Results show that at room temperature with 2.00 mmol/L dosage, MB4 achieves 99.08% anti-corrosion efficiency, surpassing MB2's 98.38%. At 313–333 K, MB4's efficiencies (93.96%–86.98%) far exceed MB2's (66.43%–51.82%), proving better temperature stability. SEM/EDS/XPS reveal both form protective films, but MB4's stronger adsorption enhances performance. Quantum chemical calculations show MB4's pyridine-4-aldehyde optimises nitrogen (N) atom electron cloud density for stronger metal interaction. Molecular dynamics (MD) simulations, mean square displacement (MSD) and free volume fraction (FFV) calculations indicate that imidazole rings adsorb on iron first, with carbon chains as hydrophobic barriers. MB4 has lower adsorption energy (−234.223 vs. −209.702 kcal·mol −1 ) and smaller free volume (13.61% vs. 14.24%), inhibiting ion diffusion. The study innovatively demonstrates para-substituted structures enhance efficiency via electronic effects and film compactness, guiding the development of temperature-resistant pickling preservatives.
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