# From the Problem of Corrosion to Green Solutions: The Role of Biosurfactants as Anti-Corrosion Agents

**Authors:** Kaio Wêdann de Oliveira, Yslla Emanuelly da Silva Faccioli, Gleice Paula de Araújo, Attilio Converti, Rita de Cássia Freire Soares da Silva, Leonie Asfora Sarubbo

PMC · DOI: 10.3390/ma19040743 · Materials · 2026-02-14

## TL;DR

This paper reviews how biosurfactants can serve as eco-friendly solutions to mitigate corrosion in industrial systems.

## Contribution

The paper provides a comprehensive review of biosurfactants as green anti-corrosion agents, emphasizing their mechanisms and industrial applications.

## Key findings

- Biosurfactants reduce corrosion by forming protective films and modifying metal interfaces.
- They offer advantages over synthetic inhibitors due to lower toxicity and environmental impact.
- Recent studies show biosurfactants are effective in maritime, petrochemical, and energy sectors.

## Abstract

Corrosion remains one of the major contemporary technological challenges, causing significant economic, environmental, and operational impacts on industrial systems. Although it is a spontaneous process inherent to metals and their alloys, its progression can be significantly mitigated by appropriate protection strategies. Traditionally, synthetic inhibitors have been widely used; however, their toxicity, environmental persistence, and increasing regulatory restrictions have prompted a search for greener alternatives. Biosurfactants stand out as promising green anticorrosive agents, acting through the formation of adsorbed films, reduction in wettability, modification of the metal–medium interface, and, in some cases, antimicrobial effects that inhibit the formation of corrosive biofilms. This review presents an integrated analysis of the main corrosion mechanisms, including uniform, localized, galvanic, and microbiologically influenced corrosion, with an emphasis on critical industrial environments such as the maritime, petrochemical, energy, and infrastructure sectors. Additionally, the main classes of biosurfactants are discussed, along with their key physical and chemical characteristics, including critical micelle concentration, thermal and saline stability, adsorption capacity, and their mechanisms of action in mitigating corrosion. Finally, the article summarizes the advances of the last decade, highlighting experimental studies, emerging applications, and technological trends that consolidate biosurfactants as viable, efficient, and environmentally safe alternatives for industrial corrosion protection.

## Full-text entities

- **Diseases:** accidents (MESH:D000081084), fatigue (MESH:D005221), cracks (MESH:D003387), injury to (MESH:D014947), cancer (MESH:D009369), acid (MESH:D011015), promyelocytic leukemia (MESH:D015473), UC (MESH:C567162), fire (MESH:D000092422), cytotoxicity (MESH:D064420), Erosion (MESH:D014077)
- **Chemicals:** rhamnolipid (MESH:C418382), Al2O3 (MESH:D000537), palm oil (MESH:D000073878), iron (MESH:D007501), phosphonates (MESH:D063065), benzene (MESH:D001554), H2O (MESH:D014867), lanthanum (MESH:D007811), Phospholipids (MESH:D010743), sorbitol (MESH:D013012), chloride (MESH:D002712), vegetable oils (MESH:D010938), molybdates (MESH:C044659), SBA-15 (MESH:C509969), HCl (MESH:D006851), tin (MESH:D014001), sodium dodecyl sulfate (MESH:D012967), acetic acid (MESH:D019342), brine (MESH:C017082), Emulsan (MESH:C036028), Copper (MESH:D003300), Sophorolipids (MESH:C000627985), Glycolipids (MESH:D006017), lepidocrocite (MESH:C000499), iron sulfide (MESH:C022597), stainless steels (MESH:D013193), fengycin (MESH:C049972), steel (MESH:D013232), Zinc (MESH:D015032), sulfide (MESH:D013440), salicylic acid (MESH:D020156), sulfate (MESH:D013431), O (MESH:D010100), P (MESH:D010758), Phosphatidylinositol (MESH:D010716), salt (MESH:D012492), phosphate (MESH:D010710), chitosan (MESH:D048271), Zn(OH)2 (MESH:C052745), acids (MESH:D000143), sugars (MESH:D000073893), nitrate (MESH:D009566), cyclic peptides (MESH:D010456), NaCl (MESH:D012965), chromates (MESH:D002840), silicates (MESH:D017640), goethite (MESH:C094886), Metal (MESH:D008670), Polymeric (MESH:D011108), C (MESH:D002244), ester (MESH:D004952), N (MESH:D009584), carboxylic acids (MESH:D002264), Ni (MESH:D009532), ammonium (MESH:D064751), piperazine (MESH:D000077489), cerium hydroxide (MESH:C048873), ammonium sulfate (MESH:D000645), OH- (MESH:C031356), HF (MESH:D006195)
- **Species:** Bacillus licheniformis (species) [taxon 1402], Penicillium citrinum (species) [taxon 5077], Saccharomyces cerevisiae (baker's yeast, species) [taxon 4932], Halomonas (genus) [taxon 2745], PX clade (clade) [taxon 569578], Pseudomonas (RNA similarity group I, genus) [taxon 286], Calamagrostis arenaria (species) [taxon 96047], Solanum tuberosum (potatoes, species) [taxon 4113], Aspergillus (genus) [taxon 5052], Starmerella (genus) [taxon 75735], Arthrobacter (genus) [taxon 1663], Acinetobacter calcoaceticus (species) [taxon 471], Homo sapiens (human, species) [taxon 9606], Starmerella bombicola (species) [taxon 75736], Bacteria Latreille et al. 1825 (Bacteria stick insect, genus) [taxon 629395], Rhodococcus (genus) [taxon 1661425]
- **Cell lines:** MCF-7 — Homo sapiens (Human), Invasive breast carcinoma of no special type, Cancer cell line (CVCL_0031), HepG2 — Homo sapiens (Human), Hepatoblastoma, Cancer cell line (CVCL_0027), St37 — Homo sapiens (Human), Gastric carcinoma, Cancer cell line (CVCL_H265), CaCo-2 — Homo sapiens (Human), Colon adenocarcinoma, Cancer cell line (CVCL_0025)

## Full text

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## Figures

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## References

233 references — full list in the complete paper: https://tomesphere.com/paper/PMC12942546/full.md

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Source: https://tomesphere.com/paper/PMC12942546