辣木叶提取物对冷轧钢在硫酸介质中的缓蚀性能

doi:10.11902/1005.4537.2025.207

中国腐蚀与防护学报

2026, Vol. 46

Issue (3): 743-755 CSTR: 32134.14.1005.4537.2025.207 DOI: 10.11902/1005.4537.2025.207

研究报告

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辣木叶提取物对冷轧钢在硫酸介质中的缓蚀性能

郭崇楠¹, 朱平¹^,², 唐莉清¹, 李向红¹, 徐娟¹(

)

^1.西南林业大学材料与化学工程学院林业生物质资源高效利用技术国家地方联合工程研究中心昆明 650224
^2.云南省特种设备安全检测研究院昆明 650228

Inhibitory Performance of Moringa Leaf Extract on Corrosion of Steel in H₂SO₄ Solution

GUO Chongnan¹, ZHU Ping¹^,², TANG Liqing¹, LI Xianghong¹, XU Juan¹(

)

^1.National Joint Engineering Research Center for Highly-Efficient Utilization Technology of Forestry Resources, College of Materials and Chemical Engineering, Southwest Forestry University, Kunming 650224, China
^2.Yunnan Provincial Special Equipment Safety Testing and Research Institute, Kunming 650228, China

引用本文:

郭崇楠, 朱平, 唐莉清, 李向红, 徐娟. 辣木叶提取物对冷轧钢在硫酸介质中的缓蚀性能[J]. 中国腐蚀与防护学报, 2026, 46(3): 743-755.
Chongnan GUO, Ping ZHU, Liqing TANG, Xianghong LI, Juan XU. Inhibitory Performance of Moringa Leaf Extract on Corrosion of Steel in H₂SO₄ Solution[J]. Journal of Chinese Society for Corrosion and protection, 2026, 46(3): 743-755.

全文: PDF(9975 KB) HTML

摘要:

采用超声辅助提取法制备获得辣木叶提取物(MLE)，并利用傅立叶红外光谱(FTIR)分析了MLE中官能团组成。采用失重分析法、电化学测试法、原子力显微镜(AFM)以及X射线光电子能谱(XPS)等多种技术手段，系统研究了MLE在0.5 mol/L硫酸(H₂SO₄)溶液中对冷轧钢的缓蚀性能。结果表明，在30 ℃下，添加100 mg/L MLE对冷轧钢的缓蚀率可达到90.06%；MLE在冷轧钢表面的吸附遵循Langmuir和Freundlich吸附等温模型，计算得到的标准吸附Gibbs自由能(∆G⁰)的范围为-26.12到-31.86 kJ·mol^-1，表明吸附主要是以物理吸附与化学吸附结合的混合型吸附模式，并证实MLE在30 ℃下具有最佳吸附性能；电化学分析证实MLE是一种混合型抑制剂，其作用机制主要是增大钢/酸界面电荷转移电阻，有效抑制电化学腐蚀过程；MLE的存在会使钢表面粗糙度和亲水度降低；XPS分析则进一步揭示MLE在钢表面形成吸附膜是其发挥缓蚀作用的关键机制，量子化学计算表明MLE中存在的含氧基团作为其活性吸附位点。本研究为高值化利用辣木叶进行工业防腐提供了一种新的思路。

关键词 ：辣木叶提取物, 硫酸, 冷轧钢, 吸附, 缓蚀剂

Abstract：

Herein, Moringa leaf extract (MLE) was prepared via an ultrasound-assisted extraction method, and of which the potential chemical functional groups were characterized by means of Fourier transform infrared spectroscopy (FTIR). Next, the corrosion inhibition performance of MLE for cold-rolled steel in 0.5 mol/L H₂SO₄ solution was systematically investigated via weight loss measurements, electrochemical measurements, atomic force microscopy (AFM), and X-ray photoelectron spectroscopy (XPS) etc. The results demonstrate that with a dosage of 100 mg/L MLE, a corrosion inhibition efficiency of 90.06% may be reached for cold-rolled steel in 0.5 mol/L H₂SO₄ solution at 30 ℃. The adsorption of MLE on the surface of cold rolled steel follows Langmuir and Freundlich isothermal models. The calculated standard adsorption Gibbs free energy (∆G⁰) ranges from -26.12 to -31.86 kJ·mol^-1, indicating that the adsorption is mainly a mixed mode of physical and chemical adsorption, and confirmed that MLE has the best adsorption performance at 30 ℃. Electrochemical analysis also confirmed that MLE acts as a mixed-type inhibitor. Its primary mechanism involves increasing the charge transfer resistance at the steel/acid interface, thereby effectively inhibiting the electrochemical corrosion process. The presence of MLE will reduce the surface roughness and hydrophilicity of steel; Furthermore, XPS analysis further revealed that the key mechanism of MLE's corrosion inhibition was the formation of an adsorption film on steel surface, quantum chemical calculations show that the oxygen-containing groups in MLE serve as active adsorption sites. It provided a new idea for the high value utilization of moringa leaves in industrial anticorrosion.

Key words： moringa leaf extract H₂SO₄ cold-rolled steel adsorption inhibitor

收稿日期: 2025-07-02 32134.14.1005.4537.2025.207

ZTFLH:

TG174

基金资助:国家自然科学基金(32360362);国家自然科学基金(52161016);云南省农业基础研究联合专项重点项目(202301BD070001-158);云南省专家工作站项目(202305AF150009);西南林业大学博士研究启动基金(110224051)

通讯作者: 徐娟，E-mail：58045846@qq.com，研究方向为生物质资源高值化利用

Corresponding author: XU Juan, E-mail: 58045846@qq.com

作者简介: 郭崇楠，男，2002年生，硕士生

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https://www.jcscp.org/CN/10.11902/1005.4537.2025.207 或 https://www.jcscp.org/CN/Y2026/V46/I3/743

图1 MLE的提取过程

图2 不同温度下钢片的腐蚀速率和缓蚀率与MLE浓度关系图

图3 不同温度下冷轧钢的Langmuir和Freundlich拟合直线

表1 不同温度下MLE吸附在冷轧钢表面的Langmuir和Freundlich线性拟合参数

图4 冷轧钢腐蚀速率相关的Arrhenius方程和过渡态方程拟合直线以及腐蚀动力学参数随浓度的关系

表2 不同温度下MLE在冷轧钢表面的腐蚀动力学参数

图5 30 ℃下冷轧钢在添加不同浓度MLE的0.5 mol/L H2SO4溶液的电化学测试

表3 动电位Tafel外推法拟合参数

表4 30 ℃下冷轧钢在未添加与添加不同浓度MLE的H2SO4溶液中的Rs(QRt)等效电路拟合参数

图6 30 ℃下冷轧钢在未添加与添加不同浓度MLE的0.5 mol/L H2SO4浸泡6 h后的表面接触角及表面金相

图7 30 ℃下冷轧钢在未添加与添加100 mg/L MLE的0.5 mol/L H2SO4浸泡6 h后的AFM表面形貌

表5 AFM粗糙度参数

图8 冷轧钢在30 ℃下添加100 mg/L MLE的0.5 mol/L H2SO4溶液中浸泡6 h后的XPS测试

图9 MLE中所含有3种不同结构的QC计算和MLE的FTIR谱图

表6 MLE中3种不同类型分子的QC计算参数

图10 MLE的缓蚀机理图

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