Phytotechnology for Per- and Polyfluoroalkyl Substances (PFAS) Treatment: Mechanistic Insights into Environmental Behavior, Plant Uptake, and Phytomanagement Opportunities
Setyo Budi Kurniawan, Suriya Vathi Subramanian, Hassimi Abu Hasan, Hanies Ambarsari, Dian Andriani, Nurfitri Abdul Gafur, Meidaliyantisyah, Fitri Yola Amandita, Tuti Suryati, Rina Andriyani, Arina Yuthi Apriyana, Ekaputra Agung Priantoro, Dominikus Hariawan Akhadi, Tarzan Sembiring, Muhammad Fauzul ImronPer- and polyfluoroalkyl substances (PFAS) are ultra-persistent contaminants characterized by exceptional chemical stability, high mobility, and widespread environmental occurrence, posing significant challenges for remediation. Phytotechnology has emerged as a promising nature-based approach, yet its effectiveness is strongly governed by PFAS physicochemical properties and plant–soil interactions. This review provides a mechanistic synthesis linking PFAS environmental behavior with phytotechnology performance by examining PFAS sources, transport pathways, and structure-dependent properties that control persistence, partitioning, and mobility, with an emphasis on differences between short- and long-chain compounds. These characteristics determine bioavailability and influence treatment outcomes. Plant uptake mechanisms, including root absorption, xylem translocation, and tissue accumulation, are discussed alongside rhizosphere processes such as sorption, microbial interactions, and hydrological dynamics that regulate PFAS retention and redistribution. Current evidence indicates that phytotechnology functions primarily as a form of phytomanagement rather than a destructive solution, as mineralization is limited and field-scale treatment remains low. Instead, plant–soil–microbe systems reduce PFAS mobility and exposure through stabilization and sequestration. Future research should prioritize strategies for short-chain PFAS, integration with sorptive amendments, and data-driven approaches to optimize phytomanagement performance.