Environmental Oriented Electrochemistry 1st edition by CAC Sequeira ISBN 0080875187 9780080875187

PART I: WATER CARE AND TREATMENT PROCESSES

Chapter 1. Electrochemical techniques for the treatment of dilute metal-ion solutions

The scope for electrochemical techniques

Typical electrochemical reactions

Cell design considerations

Classification of electrochemical reactors

Examples of reactor designs and their performance

Summary

References

Chapter 2. Electrochemical methods for purification of waste waters

Introduction

Electrochemical background for the deposition of heavy metals

Plate electrolyser

Electrolyser with a fluidized bed

Other diaphragmless electrolysers

Electrolysers involving a diaphragm

Other, similar electrolyser types

Electrochemical destruction of toxic organic compounds

References

Chapter 3. Electrochemical oxidation of organic pollutants for wastewater treatment

Introduction

Experimental details

Definition of global parameters for the electrochemical treatment

Possibilities of the electrochemical oxidation of organics for wastewater treatment

Analysis of reaction products at Pt and SnO2 anodes

Comparison between electrochemical and chemical oxidation

Mechanism of electrochemical oxidation of phenol for wastewater treatment

Pilot plant experiments for the treatment of industrial wastewater

References

Chapter 4. Electrochemical oxidant generation for wastewater treatment

Introduction

Ozone

Hydrogen peroxide

Potassium permanganate

Chlorine and hypochlorite

Chlorine dioxide

References

PART II: BATTERIES AND ENVIRONMENT

Chapter 5. Batteries and the environment

Introduction

The environmental problem

Regulatory aspects

The management of discarded batteries

Battery recycling

Battery improvements

Administrative structures

Sources of general information related to the battery

References

Chapter 6. Alkaline manganese dioxide – zinc batteries. Primary and rechargeable cells with and with

Introduction

Primary alkaline manganese dioxide – zinc batteries (PAM cells)

Rechargeable alkaline manganese dioxide – zinc batteries (RAM cells)

Batteries and environment

Toxicology

Conclusions

References

Chapter 7. Electrochemical generators and the environment. Fuel cells and metal/air batteries

Introduction

Fuel cells

Metal/air batteries

Conclusion

References

Chapter 8. The prospective role of magnesium in the development of environment-friendly solid-state

Introduction

Experimental results and discussion

Conclusions

References

PART III: SENSORS FOR POLLUTION CONTROL

Chapter 9. Overview of gas sensors for environmental use

Importance of environmental problems and growing needs for gas sensing

Methods of gas sensing related with environmental problems

Recent researches and developments of gas sensors for environmental use

Application to pollution control

Future scope

References

Chapter 10. Piezoelectric crystal detectors for environmental pollutants

Introduction

Experimental

Conclusions

References

Chapter 11. me electrochemistry of gases of medical interest and electrochemical gas sensors

Introduction

Membrane covered sensors

Oxygen: sensors and electrochemistry

Carbon dioxide

Anaesthetic gases

Solid state gas sensors

References

PART IV: TECHNIQUES FOR POLLUTION MONITORING

Chapter 12. Environmental pollution monitoring using DC pulse techniques

Introduction

Electrochemical monitoring

The DC pulse system

Monitoring environmental pollution

Rainfall pollution

Monitoring soil contamination with Kuwaiti oil field burn products

Monitoring pollution of seawater with Kuwaiti oil contaminants

Conclusions and recommendations

References

Chapter 13. Bacterial-environmental interactions in corrosion on buried pipes

Introduction

Effects of bacterial ecology on underground corrosion

Experimental procedures of laboratory study on local action cell corrosion

Results and discussion of laboratory study on local action cell corrosion

Conclusions

References

Chapter 14. Influence of ohmic drop on the determination of electrochemicul parameters

Introduction

General considerations

Monitoring by a two-electrode technique

Importance of the environment

Numerical methods

Mathematical schematization

Influence of the ohmic drop on the corrosion rate

Explicit form of the function i(ΔE)

Inversion through power series expansion

Numerical determination of Rs

Experimental techniques

Conclusions

References

PART V: PHOTOELECTROCHEMISTRY FOR A CLEANER ENVIRONMENT

Chapter 15. Semiconductor photoelectrochemistry for cleaner environment: utilization of solar energy

Introduction

Semiconductor/electrolyte system in dark and upon illumination

PEC cells for solar-to-electrical energy conversion

PEC cells for solar-to-chemical energy conversion

Semiconductor dispersions for providing cleaner environments

Concluding remarks

References

Chapter 16. Prospective usage of photoelectrochemistry for environmental control

Introduction

Photoelectrochemical reduction of CO2

Photocatalytic reduction of CO2

Photoelectrochemical decomposition of H2S

Photoelectrochemical conversion of SO2

Photoelectrochemical reduction of O2

Photoelectrochemical generation of H2

Chapter 17. Electrochemical storage of solar energy

Introduction

Solar-hydrogen plant: Principles of design and state-of-the -art

Solar-hydrogen plant: Simulation

Solar-hydrogen plant: Optimization

Optimization of the plant “solar array + electrolyzer + secondary battery”

References

PART VI: MISCELLANEOUS ENVIRONMENTALLY ORIENTATED ELECTROCHEMICAL PROCESSES

Chapter 18. Electrodialytic membrane procesaea and their practical application

Introduction

Properties and structures of ion-exchange membranes

Electrodialytic processes as unit operation

Other electrically driven membrane processes

Conclusions

References

Chapter 19. Removal of H2S through an electrochemical membrane separator

Introduction

Technical discussion

Experimental

Experimental run results

Economic projection

Conclusions

References

Chapter 20. Electrochemical treatment of mixed and hazardous wastes

Introduction

State-of-the-art

Examples of mixed-waste feed streams

Process chemistry

Electrochemical generation of oxidants in batch reactor

Destruction and coulombic efficiencies for ME0 process

Reaction intermediates formed during ME0 of glycol and benzene

Reaction mechanisms for ME0 of ethylene glycol and benzene

Theoretical model for electrochemical batch reactor

Application of model to the ME0 of glycol by silver (11)

Maximum mediator concentration – no organics

Other recommended reading

Summary

References

Chapter 21. Magnetic field effects in environmental control involving electrolytes

Preamble and motivation

Theoretical foundations

The magnetic field effect in the treatment of waste fluids and effluents

The magnetic field effect on corrosion in electrolytes

The magnetic field effect on natural bodies of water

Critique and concluding remarks

References

Chapter 22. Soil decontamination using electrokinetic processing

Introduction

Theoretical

Results

Summary

References

Chapter 23. Electrochemical utilization of hydrochloric mid – waste of chlororganic production

Hydrochloric acid electrolysis producing chlorineand hydrogen

Hydrochloric acid electrolysis producing hydrogen and chlororganic compounds

References

Chapter 24. Electrocatalysis for environmentally orientated electrochemical processes and environmen

Introduction

Environmental problems in electrochemical processes

The special role of hydrogen and oxygen electrodes

Examples for electrolytic applications of oxygen and hydrogen electrodes

Conclusions

References

Author Index

Subject Index