Carbon steel anticorrosion performance and mechanism of sodium lignosulfonate

Lignin is a typical biological macromolecule with a three-dimensional network structure and abundant functional groups. It has excellent ionic complexation ability and amphiphilic molecular structure characteristics. In this study, the carbon steel anticorrosion performance of sodium lignosulfonate...

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Veröffentlicht in:	Rare metals 2024, Vol.43 (1), p.356-365
Hauptverfasser:	Liao, Bo-Kai, Quan, Rui-Xuan, Feng, Ping-Xian, Wang, Huan, Wang, Wei, Niu, Li
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Sprache:	eng
Schlagworte:	Biomaterials Carbon steels Chemistry and Materials Science Corrosion prevention Corrosion tests Energy Functional groups Functional materials Killed steels Lignosulfonates Materials Engineering Materials Science Metallic Materials Molecular structure Nanoscale Science and Technology Original Article Physical Chemistry Sodium Surface properties Weight loss measurement
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creator	Liao, Bo-Kai Quan, Rui-Xuan Feng, Ping-Xian Wang, Huan Wang, Wei Niu, Li
description	Lignin is a typical biological macromolecule with a three-dimensional network structure and abundant functional groups. It has excellent ionic complexation ability and amphiphilic molecular structure characteristics. In this study, the carbon steel anticorrosion performance of sodium lignosulfonate (SLS) in an acid solution was evaluated using the weight loss method, electrochemical measurements, scanning vibration electrode technique (SVET), and surface characterization methods. SLS exhibited excellent corrosion inhibition efficiency for Q235 carbon steel in 1 mol·L -1 HCl, reaching a maximum value of 98%. A low SLS concentration of 20 mg·L -1 resulted in the maximum corrosion inhibition efficiency, which remained nearly constant at higher SLS concentrations. The SVET test demonstrated that the formation of an SLS adsorption film can impede corrosion. This study confirms the significance of the application of green biomass resources in the field of metal corrosion protection and green functional materials. Graphical abstract
doi_str_mv	10.1007/s12598-023-02404-y
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subjects	Biomaterials Carbon steels Chemistry and Materials Science Corrosion prevention Corrosion tests Energy Functional groups Functional materials Killed steels Lignosulfonates Materials Engineering Materials Science Metallic Materials Molecular structure Nanoscale Science and Technology Original Article Physical Chemistry Sodium Surface properties Weight loss measurement
title	Carbon steel anticorrosion performance and mechanism of sodium lignosulfonate
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