Biological Fuel Cells
-10%
portes grátis
Biological Fuel Cells
Fundamental to Applications
Rahimnejad, Mostafa
Elsevier - Health Sciences Division
03/2023
508
Mole
Inglês
9780323857116
15 a 20 dias
Descrição não disponível.
Part 1: Constituents, structure, materials and measurement with conceptual, practical and economical views
1. Introduction to microbial fuel cell technology
2. Electrochemical and microbiological concepts of MFCs
3. Anode electrodes in MFCs
4. Cathode electrodes in MFCs
5. Energy and power measurement methods in MFCs
6. MFCs designing and performance
7. Separators and membranes
8. Supercapacitors and MFCs
9. MFCs' challenges and the potential solutions
10. MFCs' commercialization and economic analysis
Part 2: MFCs' applications
11. Electricity generation
12. Wastewater treatment
13. Bio-hydrogen generation and MECs
14. CO2 reduction and MES
15. Bioremediation by MFC technology
16. MFC based biosensors
17. Sediment microbial fuel cell
18. Future applications
1. Introduction to microbial fuel cell technology
2. Electrochemical and microbiological concepts of MFCs
3. Anode electrodes in MFCs
4. Cathode electrodes in MFCs
5. Energy and power measurement methods in MFCs
6. MFCs designing and performance
7. Separators and membranes
8. Supercapacitors and MFCs
9. MFCs' challenges and the potential solutions
10. MFCs' commercialization and economic analysis
Part 2: MFCs' applications
11. Electricity generation
12. Wastewater treatment
13. Bio-hydrogen generation and MECs
14. CO2 reduction and MES
15. Bioremediation by MFC technology
16. MFC based biosensors
17. Sediment microbial fuel cell
18. Future applications
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Anode electrode; Antifouling features; Applications; Benthic MFC; Bioconversion of chemical energy; Bioelectricity generation; Bioelectrochemical conversion; Bioelectrochemical systems; Bioelectrodeposion; Biofilm activity; Biofilm characterization; Biofouling assessment; Biofouling formation; Biohydrogen generation; Biological fuel cell; Biological fuel cells; Bioremediation; Biosensors; Cathode requirements; Cathode structure; Cathodic surface treatment; CO2 capture; Commercialization; Constructed wetland MFC; Cost-effective resources; Direct electron transfer; Economic analysis; Economic issues; Electricity generation; Electroactive biofilm; Electrochemical catalysis; Electrochemical methods; Electrochemical performance; Electrode kinetics; Electronic conductivity; Electrotrophic microorganisms; Enzymatic fuel cell; Enzyme-based fuel cells; Exoelectrogenic eukaryotes; Exoelectrogenic prokaryotes; Field trials; Fouling challenges; Heavy metal removal; Heavy metals; Hybrid systems; Indirect electron transfer; Interspecies electron transfer; Ion transfer; KeywordMicrobial fuel cell; Large-scale implementation; Low energy device; Measurements; MEC architecture; Membrane design; Membrane kinetics; Membrane materials; Membrane requirements; Methanogenesis; MFC configurations; Microbial communities; Microbial desalination cells; Microbial electrolysis cell; Microbial electrosynthesis; Microbial fuel cell; Microbial fuel cell supercapacitive mode; Microbial fuel cells; Microorganisms; Nanostructured carbon; Operating conditions; Oxygen reduction reaction; Paper-based MFC designs; Photosynthetic microbial fuel cells; Photosynthetic SMFC; Power indicator; Power management systems; Practical implementation; Remote sensors; Removal environmental pollutants; Robotics; Sediment microbial fuel cell; Sediment microbial fuel cells; Self-sustainability; Sensors; Soil microbial fuel cell; Solar-enhanced microbial fuel cells; Stackable reactor design; Supercapacitive electrodes; Supercapacitive microbial fuel cell; Surface treatment; Urine-fed systems; Value-added bio-based products; Voltage losses; Wastewater treatment
Part 1: Constituents, structure, materials and measurement with conceptual, practical and economical views
1. Introduction to microbial fuel cell technology
2. Electrochemical and microbiological concepts of MFCs
3. Anode electrodes in MFCs
4. Cathode electrodes in MFCs
5. Energy and power measurement methods in MFCs
6. MFCs designing and performance
7. Separators and membranes
8. Supercapacitors and MFCs
9. MFCs' challenges and the potential solutions
10. MFCs' commercialization and economic analysis
Part 2: MFCs' applications
11. Electricity generation
12. Wastewater treatment
13. Bio-hydrogen generation and MECs
14. CO2 reduction and MES
15. Bioremediation by MFC technology
16. MFC based biosensors
17. Sediment microbial fuel cell
18. Future applications
1. Introduction to microbial fuel cell technology
2. Electrochemical and microbiological concepts of MFCs
3. Anode electrodes in MFCs
4. Cathode electrodes in MFCs
5. Energy and power measurement methods in MFCs
6. MFCs designing and performance
7. Separators and membranes
8. Supercapacitors and MFCs
9. MFCs' challenges and the potential solutions
10. MFCs' commercialization and economic analysis
Part 2: MFCs' applications
11. Electricity generation
12. Wastewater treatment
13. Bio-hydrogen generation and MECs
14. CO2 reduction and MES
15. Bioremediation by MFC technology
16. MFC based biosensors
17. Sediment microbial fuel cell
18. Future applications
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Anode electrode; Antifouling features; Applications; Benthic MFC; Bioconversion of chemical energy; Bioelectricity generation; Bioelectrochemical conversion; Bioelectrochemical systems; Bioelectrodeposion; Biofilm activity; Biofilm characterization; Biofouling assessment; Biofouling formation; Biohydrogen generation; Biological fuel cell; Biological fuel cells; Bioremediation; Biosensors; Cathode requirements; Cathode structure; Cathodic surface treatment; CO2 capture; Commercialization; Constructed wetland MFC; Cost-effective resources; Direct electron transfer; Economic analysis; Economic issues; Electricity generation; Electroactive biofilm; Electrochemical catalysis; Electrochemical methods; Electrochemical performance; Electrode kinetics; Electronic conductivity; Electrotrophic microorganisms; Enzymatic fuel cell; Enzyme-based fuel cells; Exoelectrogenic eukaryotes; Exoelectrogenic prokaryotes; Field trials; Fouling challenges; Heavy metal removal; Heavy metals; Hybrid systems; Indirect electron transfer; Interspecies electron transfer; Ion transfer; KeywordMicrobial fuel cell; Large-scale implementation; Low energy device; Measurements; MEC architecture; Membrane design; Membrane kinetics; Membrane materials; Membrane requirements; Methanogenesis; MFC configurations; Microbial communities; Microbial desalination cells; Microbial electrolysis cell; Microbial electrosynthesis; Microbial fuel cell; Microbial fuel cell supercapacitive mode; Microbial fuel cells; Microorganisms; Nanostructured carbon; Operating conditions; Oxygen reduction reaction; Paper-based MFC designs; Photosynthetic microbial fuel cells; Photosynthetic SMFC; Power indicator; Power management systems; Practical implementation; Remote sensors; Removal environmental pollutants; Robotics; Sediment microbial fuel cell; Sediment microbial fuel cells; Self-sustainability; Sensors; Soil microbial fuel cell; Solar-enhanced microbial fuel cells; Stackable reactor design; Supercapacitive electrodes; Supercapacitive microbial fuel cell; Surface treatment; Urine-fed systems; Value-added bio-based products; Voltage losses; Wastewater treatment
