Přehled o publikaci
2020
Advanced oxidation processes for the removal of cyanobacterial toxins from drinking water
SCHNEIDER, Marcel and Luděk BLÁHABasic information
Original name
Advanced oxidation processes for the removal of cyanobacterial toxins from drinking water
Authors
SCHNEIDER, Marcel (276 Germany, belonging to the institution) and Luděk BLÁHA (203 Czech Republic, guarantor, belonging to the institution)
Edition
Environmental Sciences Europe, New York, Springer, 2020, 2190-4707
Other information
Language
English
Type of outcome
Article in a journal
Country of publisher
United States of America
Confidentiality degree
is not subject to a state or trade secret
References:
RIV identification code
RIV/00216224:14310/20:00116473
Organization
Přírodovědecká fakulta – Repository – Repository
UT WoS
000551914800001
EID Scopus
2-s2.0-85087720875
Keywords in English
AOP; Cyanotoxin; Cylindrospermopsin; Fenton oxidation; Hydroxyl radical; Microcystin; Ozone; Sulfate radical; UV; Water treatment
Links
EF17_043/0009632, research and development project. 722493, interní kód Repo. 857560, interní kód Repo. RECETOX RI, large research infrastructures.
Changed: 3/6/2025 00:50, RNDr. Daniel Jakubík
Abstract
V originále
Drinking water production faces many different challenges with one of them being naturally produced cyanobacterial toxins. Since pollutants become more abundant and persistent today, conventional water treatment is often no longer sufficient to provide adequate removal. Among other emerging technologies, advanced oxidation processes (AOPs) have a great potential to appropriately tackle this issue. This review addresses the economic and health risks posed by cyanotoxins and discusses their removal from drinking water by AOPs. The current state of knowledge on AOPs and their application for cyanotoxin degradation is synthesized to provide an overview on available techniques and effects of water quality, toxin- and technique-specific parameters on their degradation efficacy. The different AOPs are compared based on their efficiency and applicability, considering economic, practical and environmental aspects and their potential to generate toxic disinfection byproducts. For future research, more relevant studies to include the degradation of less-explored cyanotoxins, toxin mixtures in actual surface water, assessment of residual toxicity and scale-up are recommended. Since actual surface water most likely contains more than just cyanotoxins, a multi-barrier approach consisting of a series of different physical, biological and chemical-especially oxidative-treatment steps is inevitable to ensure safe and high-quality drinking water.