DEVELOPMENT OF BIOLOGICAL TECHNOLOGY AND NANO TIO2 MODIFIED CERAMIC MEMBRANES FOR RECIRCULATION OF SHRIMP AQUACULTURE WASTEWATER: BOTTLENECKS AND PROSPECTS
- Thuy Ngan Bui Thi - School of Chemistry and Life Sciences, Hanoi University of Science and Technology, Viet Nam - Center for Advanced Materials and Environmental Technology, National Center for Technological Progress, Viet Nam
- Xuan Quang Chu - Center for Advanced Materials and Environmental Technology, National Center for Technological Progress, Viet Nam
- Van Tuyen Nguyen - University of Transport Technology, Viet Nam
- Khac-Uan Do - School of Chemistry and Life Sciences, Hanoi University of Science and Technology, Viet Nam
- Available online in Detritus - In Press
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Copyright: © 2026 CISA Publisher
Abstract
The shrimp aquaculture industry generates wastewater rich in organic matter, suspended solids, nutrients, pathogens, and residual antibiotics, posing environmental challenges. Conventional biological treatments, including constructed wetlands, biofloc systems, microalgae cultivation, and recirculating aquaculture systems (RAS), are widely used due to low cost and environmental compatibility; however, their performance is often constrained by recalcitrant organics and unstable effluent quality under water reuse conditions. This review focuses on recent advances in integrating biological processes with nano TiO2 modified ceramic membranes. Ceramic membranes provide mechanical strength, chemical stability, and tolerance to saline and harsh conditions, while TiO2 modification enhances hydrophilicity, antimicrobial activity, and photocatalytic degradation of refractory pollutants. Reported studies show chemical oxygen demand (COD) removal efficiencies of 85 – 92% and near complete total suspended solids (TSS) removal, while TiO2 modified membranes achieve over 90% removal of dyes, proteins, and oils and reduce membrane fouling under ultraviolet (UV) irradiation. Membrane fouling mechanisms, photocatalytic performance, bioreactor integration, and economic considerations are discussed. The combination of biological treatment and modified ceramic membranes represents a promising approach for enhancing water reuse and long term treatment stability in shrimp aquaculture.Keywords
- Shrimp aquaculture wastewater
- Modified ceramic membrane
- Nano-TiO₂
- Biological treatment
- Water reuse
- Photocatalytic process
Editorial History
- Received: 12 Feb 2026
- Revised: 08 Apr 2026
- Accepted: 11 May 2026
- Available online: 26 May 2026
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