由硫芬衍生的新型缓蚀剂的实验与理论结合研究

Ali M. Resen, Ayad N. Jasim, Heba S. Qasim, Mahdi M. Hanoon, Mohammed H. H. Al-Kaabi, Ahmed A. Al-Amiery, Waleed K. Al-Azzawi
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摘要

摘要本研究以噻吩为原料合成了一种新型缓蚀剂,并通过实验和理论两种方法对其缓蚀性能进行了综合评价。我们的研究包括采用质量损失测试和电化学技术的实验评估。此外,我们进行了计算研究,深入研究了抑制剂的电子结构和键特性,旨在阐明其抑制机制。研究结果表明,合成的缓蚀剂具有显著的抑制效果,证明了其对低碳钢的防腐效果。具体来说,噻吩衍生物表现出令人印象深刻的92.8%的抑制效率,强调了它作为低碳钢的强大缓蚀剂的潜力。此外,本研究还对噻吩衍生物作为缓蚀剂的条件进行了优化。我们的研究表明,在0.5 mM的浓度和303 K的温度下可以达到最有效的抑制效果。为了阐明缓蚀剂与低碳钢表面的相互作用,我们应用了Langmuir吸附等温线概念,揭示了噻吩衍生物在金属表面的物理和化学吸附过程。我们的研究表明,缓蚀剂的加入显著降低了金属的腐蚀速率。我们的计算结果进一步强化了这些实验结果,表明抑制剂在金属表面形成稳定的吸附配合物。实验和计算方法的双重证实增强了对缓蚀剂缓蚀效果的信心。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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A combined experimental and theoretical study of a novel corrosion inhibitor derived from thiophen

In this study, we synthesized a novel corrosion inhibitor derived from thiophene and conducted a comprehensive evaluation of its inhibitory properties through both experimental and theoretical approaches. Our investigation encompassed experimental assessments employing Mass loss tests and electrochemical techniques. Additionally, we performed computational studies to delve into the electronic structure and bonding characteristics of the inhibitor, aiming to elucidate its inhibitory mechanism. Our findings revealed that the synthesized inhibitor displayed remarkable inhibitory efficiency, demonstrating its effectiveness in preventing the corrosion of mild steel. Specifically, the thiophene derivative exhibited an impressive inhibitory efficiency of 92.8%, underscoring its potential as a robust corrosion inhibitor for mild steel. Furthermore, this study delved into optimizing the conditions for employing the thiophene derivative as a corrosion inhibitor. Our investigation revealed that the most effective inhibition was achieved at a concentration of 0.5 mM and a temperature of 303 K. To elucidate the interaction between the inhibitor and the mild steel surface, we applied the Langmuir adsorption isotherm concept, shedding light on both the physical and chemical adsorption processes of the thiophene derivative on the metal's surface. Our investigations demonstrated that the addition of the inhibitor significantly reduced the corrosion rate of the metal. Our computational results further reinforced these experimental findings, indicating that the inhibitor formed stable adsorption complexes on the metal surface. This dual confirmation from experimental and computational approaches strengthens the confidence in the inhibitor's efficacy in mitigating corrosion.

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Issue Information Front Cover: Carbon Neutralization, Volume 3, Issue 6, November 2024 Inside Back Cover Image: Carbon Neutralization, Volume 3, Issue 6, November 2024 Back Cover Image: Carbon Neutralization, Volume 3, Issue 6, November 2024 A chronicle of titanium niobium oxide materials for high-performance lithium-ion batteries: From laboratory to industry
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