Eduardo Jacob-Lopes,
Leila Queiroz Zepka,
Mariany Costa Depra
Elsevier Science
e druk, 2024
9780443140587
Algal Bioreactors
Vol 1: Science, Engineering and Technology of upstream processes
Specificaties
Paperback, blz.
|
Engels
Elsevier Science |
2024
ISBN13: 9780443140587
Rubricering
Onderdeel van serie
Woodhead Series in Bioenergy
Levertijd ongeveer 9 werkdagen
Gratis verzonden
Samenvatting
Algal Bioreactors: Science, Engineering and Technology of Upstream Processes, Volume One, is part of a comprehensive two-volume set that provides all of the knowledge needed to design, develop, and operate algal bioreactors for the production of renewable resources. Supported by critical parameters and properties, mathematical models and calculations, methods, and practical real-world case studies, readers will find everything they need to know on the upstream and downstream processes of algal bioreactors for renewable resource production.
Bringing together renowned experts in microalgal biotechnology, this book will help researchers, scientists, and engineers from academia and industry overcome barriers and advance the production of renewable resources and renewable energy from algae. Students will also find invaluable explanations of the fundamentals and key principles of algal bioreactors, making it an accessible read for students of engineering, microbiology, biochemistry, biotechnology, and environmental sciences.
Specificaties
Inhoudsopgave
Part I - Fundamentals of algae bioreactors<br>1. Introduction to algal bioreactors: The biotechnology core<br>2. Algae strains in bioreactors: the adaptability of commercial and emerging species for renewable resource production<br>3. Principles of interactions between physiology and bioreactor design<br>4. Global market of algae bioproducts from bioreactor systems<br>5. Intellectual property and innovation trends applied to algae bioreactors<br><br>Part II – Science and engineering of algae bioreactors<br>6. Predictive models of algae growth in bioreactors<br>7. Optimal growth and culture conditions for algae in bioreactors<br>8. Hydrodynamic performance of algae bioreactors<br>9. Transfer phenomena in algae bioreactors<br>10. Photosynthetic reactions in algae photobioreactors<br>11. Contamination control in algae bioreactors<br>12. Processes control approaches applied to bioreactor models<br>13. Physical and biokinetic processes of carbon biosequestration in algae bioreactors<br>14. Biochemicals reactions in algae bioreactors<br>15. The influence of low carbon to nitrogen (C/N ratio) on phycoremediation<br>16. Ultrasound in algal bioreactors: A Process intensification strategy for renewable resources production<br>17. Microwave application in algal bioreactors: A Process intensification strategy for renewable resources production<br>18. Computational analysis of algae bioreactors performance for renewable resources production<br>19. Internet of Things (IoT) use for remote monitoring of algae bioreactors for renewable resources production<br>20. Scale-up of algae bioreactors for renewable resources production<br>21. Installations of algae bioreactors: design and operational issues in commercial plants<br>22. Techno-economic aspects and operational costs of algae bioreactors for renewable resources production<br><br>Part III – Trends in algal bioreactors design for renewable resource production<br>23. Industrial fermenters for renewable resource production<br>24. Air-lift photobioreactors for renewable resource production<br>25. Tubular photobioreactors for renewable resource production<br>26. Flat-plate photobioreactors for renewable resource production<br>27. Column photobioreactors for renewable resource production<br>28. Bubble column photobioreactors for renewable resource production<br>29. Hybrid photobioreactors for renewable resource production<br>30. Plastic bags photobioreactors for renewable resource production<br>31. Annular photobioreactors for renewable resource production<br>32. Membrane photobioreactors for renewable resource production<br>33. Packed Bed Bioreactors for renewable resource production<br>34. Fluidized Bed Reactors for renewable resource production<br>35. Exergy analysis of algae bioreactors for renewable resources production<br>36. Design of clean-in-place systems in algal bioreactors for renewable resources production<br><br>Part IV – Bioprocesses, bioenergy, and bioproducts obtained from algae bioreactors<br>37. Enhancing anaerobic digestion processes in algae bioreactors for renewable products production<br>38. Biohydrogen production in algae bioreactors<br>39. Biodiesel production in algae bioreactors<br>40. Bioethanol production in algae bioreactors<br>41. Biomethane production in algae bioreactors<br>42. Bio-jet fuel production in algal bioreactors<br>43. Bioelectricity from microalgae-microbial fuel cell in bioreactors<br>44. Biofertilizers production in algal bioreactors<br>45. Biomass production in algae bioreactors<br>46. Proteins and amino acids production in algae bioreactors<br>47. Lipids, sterols, and fatty acids production in algae bioreactors<br>48. Pigments production in algae bioreactors<br>49. Bioreactors as core production of specific algal for food supplements<br>50. Biomedical applications of algal-based products<br><br>Part V - Environmental issues for algae bioreactors<br>51. Industrial wastewater in algae bioreactors<br>52. Algae bioreactors as strategies for heavy metal phycoremediation<br>53. Environmental assessment of algae bioreactors for renewable resources production<br>54. Carbon neutral in renewable resources from algae bioreactors: Is this possible?