LITERATURE REVIEW OF REMOVAL OF DISINFECTION BY PRODUCTS IN WATER USING MEMBRANE TECHNOLOGY
Disinfection byproducts (DbP) are organic micro-pollutants in water which is formation during disinfection. Due to its toxicity effect in ?g/L, DbPs must be removed to ensure water quality. Membrane technology is a promising method in molecular separation. This study aims to acknowledge the devel...
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| Format: | Theses |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/53387 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Disinfection byproducts (DbP) are organic micro-pollutants in water which is
formation during disinfection. Due to its toxicity effect in ?g/L, DbPs must be
removed to ensure water quality. Membrane technology is a promising method in
molecular separation. This study aims to acknowledge the development of
technology and material membrane as well as their challenges and outlook in
DbP separation.
Based on literature studies, membrane filtration including reverse osmosis (RO),
nanofiltration (NF), ultrafiltration (UF), and forward osmosis (FO) have been
developed for DbP separation. The separation mechanisms dominated by steric
and electrostatic effects. Catalytic membranes called nanoparticle-catalytic
membrane reactor (Np-CMR) were also investigated for DbP degradation
through reduction reaction, which simultantly produced organic acid. Overall, the
performance of membranes for DbP removal or degradation achieved 40-100%.
However, the development of membranes have challenges such as trade-off
between permeability and selectivity, fouling, and operating costs. This has
stimulated modification of polymer membrane with superhidrophilic and defectfree
characteristic. Hydrophilic polymers and nanoparticles including metal
oxide aquaporins, graphene oxide (GO), and metal organic framework (MOF)
have been utilized as modifier. Based on literature data, the DbP rejection or
degradation rate of modified membranes were 30-50% higher than unmodified
membranes. Furthermore, the development of nanosheet membrane materials
(thickness <100nm and nanoporous) can be considered in this field. Additionally,
the potention for produce organic acids using Np-CMR membrane may provide
usefull insight on reuse of wastewater contaminated DbP.
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