What does this research mean for the field?

Achieving sub-0.5 mg/L boron concentrations in seawater desalination requires intelligently integrated hybrid systems based on boron speciation chemistry, as no standalone technology can reliably meet this threshold at an industrial scale. Novelty: ClaimNovelty.SYNTHESIS. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The review addresses challenges in boron removal during seawater desalination and evaluates various removal strategies.

May 19, 2026Open Access

Boron paradox in reverse osmosis desalination: A comprehensive review of removal mechanisms, hybrid process design, and resource recovery

Key Points

The review addresses challenges in boron removal during seawater desalination and evaluates various removal strategies.
Examined advancements in boron removal technologies including hybrid processes and membrane architectures.
Analyzed operational practices in Gulf Cooperation Council regions for practical insights.
Critically assessed specific mechanisms governing boron transport and removal efficiency.
No standalone technology can consistently achieve <0.5 mg/L boron for irrigation standards.
Hybrid systems show potential with >75% boron rejection at seawater pH.
Intelligently integrated systems are needed for sustainable boron management at an industrial scale.

Abstract

Boron removal in seawater desalination presents a chemically distinct challenge from bulk salt rejection: at natural seawater pH, boron persists as neutral boric acid, rendering it largely impervious to the size-exclusion and Donnan-exclusion mechanisms that underpin conventional reverse osmosis (RO). Single-pass RO systems routinely exceed both the WHO drinking water guideline (2.4 mg/L) and, more critically, the irrigation threshold (0.5 mg/L), establishing the central engineering problem this review addresses. We critically examine the mechanistic basis and technological trajectory of established and emerging boron removal strategies, including advanced RO membrane architectures, forward osmosis, membrane distillation, electrodialysis, electrocoagulation, capacitive deionization, and boron-selective sorption, with explicit emphasis on how molecular-level transport mechanisms (steric hindrance, hydrogen bonding, electrostatic exclusion, and surface complexation) govern the performance boundaries of each technology class. Emerging hybrid configurations that exploit these mechanisms synergistically to reduce chemical dosing and energy demand while enabling resource recovery are critically assessed. Gulf Cooperation Council (GCC) operational practice, where the world's highest per-capita desalination capacity intersects with the most stringent boron constraints, is analyzed as a real-world technology-readiness benchmark. The review concludes that sub-0.5 mg/L boron cannot be reliably achieved at an industrial scale by any standalone technology, and that intelligently integrated, material-advanced hybrid systems designed from first principles of boron speciation chemistry represent the only sustainable path forward. • Post-RO boron polishing requires fundamentally distinct chemistry from bulk salt rejection • Boronate esterification and inner-sphere complexation govern boron-selective membrane design • LDH and cyclodextrin functionalization achieve >75% boron rejection at neutral seawater pH • BPM-assisted electrosorption eliminates NaOH dosing while enabling borate resource recovery • No standalone technology meets <0.5 mg/L irrigation threshold without hybrid integration

Boron paradox in reverse osmosis desalination: A comprehensive review of removal mechanisms, hybrid process design, and resource recovery

Key Points

Abstract

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