APPLICATION OF SILK PROTEIN HYDROLYSATE AS A POTENT ANTI-CORROSIVE AGENT FOR MILD STEEL IN HCl SOLUTION

IF 0.5 Q4 EDUCATION & EDUCATIONAL RESEARCH

Rasayan Journal of Chemistry Pub Date : 2023-01-01 DOI:10.31788/rjc.2023.1628367

V. Nijarubini, J. Mallika

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引用次数: 0

Abstract

The study focuses on broadening the application of Silk Protein Hydrolysate (SPH) towards conventional metal protection of metallic materials. The inhibitory potentials of SPH against corrosion of mild steel in 1 N HCl media are analyzed through weight loss, electrochemical, and surface morphological techniques. The assessment of the inhibitor effectiveness, kinetic and thermodynamic variables was done at the temperature of 303 – 333 K. The studies exhibited superior anti-corrosion efficacy of 93 % for 10 ppm SPH at 303 K and good maintenance in corrosion control is seen with temperature rise. The SPH assimilation at the metal surface follows the Langmuir adsorption model with free energy values lower than -20 KJ/mol. Potentiodynamic polarization studies evince the mode of corrosion protection to be mixed overall with cathodic predominance. Electrochemical impedance spectroscopy describes the resistive and capacitive behavior through Rct and Cdl values signifying the physical barrier prevailing on the metal surface. Surface monitoring through SEM-EDS reveals the firm adherence of SPH to the metallic surface, XRD study characterizes the corrosion products formed in the process. The roughness variables derived from AFM imaging remark the stable protective layer formed by the SPH molecules. The defensive film formed smoothes the metal surface leading to an enhanced water contact angle.

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丝蛋白水解物在盐酸溶液中作为低碳钢强腐蚀剂的应用

研究重点是拓宽丝蛋白水解物(SPH)在传统金属材料保护中的应用。通过失重、电化学和表面形貌技术分析了SPH在1n HCl介质中对低碳钢的腐蚀抑制电位。在303 ~ 333 K的温度下，对缓蚀剂的有效性、动力学和热力学参数进行了评价。研究表明，在303 K下，当SPH为10 ppm时，其防腐效果为93%，并且随着温度的升高，其防腐效果也很好。金属表面的SPH同化符合Langmuir吸附模型，自由能值低于-20 KJ/mol。动电位极化研究表明，腐蚀防护模式是阴极优势与整体混合的。电化学阻抗谱通过Rct和Cdl值来描述电阻和电容行为，这两个值表示金属表面普遍存在的物理屏障。SEM-EDS表面监测显示SPH与金属表面的牢固粘附，XRD研究表征了过程中形成的腐蚀产物。从AFM成像得到的粗糙度变量表明SPH分子形成了稳定的保护层。形成的防护膜使金属表面光滑，从而增强了水接触角。

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来源期刊

Rasayan Journal of Chemistry Energy-Energy (all)

CiteScore

1.90

自引率

0.00%

发文量

196

期刊介绍： RASĀYAN Journal of Chemistry [RJC] signifies a confluence of diverse streams of chemistry to stir up the cerebral powers of its contributors and readers. By introducing the journal by this name, we humbly intent to provide an open platform to all researchers, academicians and readers to showcase their ideas and research findings among the people of their own fraternity and to share their vast repository of knowledge and information. The journal seeks to embody the spirit of enquiry and innovation to augment the richness of existing chemistry literature and theories. We also aim towards making this journal an unparalleled reservoir of information and in process aspire to inculcate and expand the research aptitude.