Solar-powered Fenton-like catalytic ceramic membrane hybrid system for the advanced water treatment태양광 기반 유사펜톤산화 촉매-세라믹막 융합 고도정수처리 시스템 개발
Cu-doped Sm-CeO$_2$) and ceramic membranes were successfully developed by a novel pore-coating method. The hybrid ceramic membrane incorporated with Cu/SDC (Cu/SDC@CM) was successfully mineralized CECs at the neutral pH conditions due to the enhanced conversion of H$_2$O$_2$ into hydroxyl radicals and increased contacts between CECs and hydroxyl radical in the confined pore structures. Moreover, economic analysis verified that the H$_2$O$_2$-Cu/SDC@CM hybrid system can be operated by solar-driven energy for the energy-independent and chemical-free processes, thus, the solar-powered H$_2$O$_2$-Cu/SDC@CM hybrid system will help to supply drinking water in response to various situations where the electricity and water are scarce.; and 4) the conceptual development of the stand-alone, solar-driven, mobile and highly economic water treatment system. In conclusion, the hybrid system of novel catalyst (Cu/SDC; 3) the preparation of the catalyst-incorporated ceramic membranes hybrid system based on Fenton-like reaction (Chapter 5); 2) the fabrication of novel heterogeneous Fenton-like catalysts offering excellent catalytic performance under neutral pH conditions (Chapter 4); 1) the investigation of the occurrence and removal of target CECs from major river basins and full-scale WTPs for a case study in South Korea (Chapter 3); Advanced oxidation processes (AOPs) have been applied to mineralize the contaminants of emerging concerns (CECs) such as plasticizers, pharmaceuticals and personal care products (PPCPs), tastes & odors compounds, etc. Among state-of-art AOP technologies, Fenton-like reactions have been widely applied due to the effective generation of hydroxyl radicals (∙OH) from H$_2$O$_2$ on the surface of a heterogeneous catalyst (Fe), lower chemical expenses, less sludge generation and toxicity, and higher reusability than the classical Fenton reaction system. However, the reaction in acidic (pH 2 ~ 4) conditions with low H$_2$O$_2$ yield still hampered the practical application. Therefore, this dissertation aims
- Advisors
- 강석태researcher
- Description
- 한국과학기술원 :건설및환경공학과,
- Publisher
- 한국과학기술원
- Issue Date
- 2022
- Identifier
- 325007
- Language
- eng
- Description
학위논문(박사) - 한국과학기술원 : 건설및환경공학과, 2022.8,[viii, 118 p. :]
- Keywords
고도정수처리▼a고도산화공정▼a세라믹막▼a태양광 재생에너지▼a수산화라디칼(∙OH)▼a과산화수소(H$_2$O$_2$)▼a신종미량유기오염물질▼a물전기분해▼a유사펜톤산화 촉매▼a적정기술; Ceramic membrane▼aSolar-driven renewable energy▼aHydroxyl radicals(∙OH)▼aHydrogen peroxide(H$_2$O$_2$)▼aContaminants of emerging concerns (CECs)▼aWater electrolysis▼aFenton-like catalyst▼aAppropriate technology; Advanced oxidation processes (AOPs); Advanced water treatment processes
- Appears in Collection
- CE-Theses_Ph.D.(박사논문)
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