Mehmood / Malik / Ralph | Algae Biotechnology | Buch | 978-0-443-34063-5 | sack.de

Buch, Englisch, 350 Seiten, Format (B × H): 191 mm x 235 mm

Mehmood / Malik / Ralph

Algae Biotechnology


Decarbonization, Resource Recovery, and Bioproducts

Buch, Englisch, 350 Seiten, Format (B × H): 191 mm x 235 mm

ISBN: 978-0-443-34063-5
Verlag: Elsevier Science

Algae Biotechnology: Decarbonization, Resource Recovery, and Bioproducts provides a comprehensive collection of chapters that covers topics such as carbon capture using microalgae, photosynthetic resource recovery, and biotransformation of algae biomass into energy and bioproducts. The book highlights non-traditional and novel opportunities for algae-based carbon capture and bioprocessing, offering insights for entrepreneurs and industrialists. It presents trendy and robust approaches in algae bioprocessing, showcasing the potential applications of microalgae in various industries. The book describes challenges and opportunities of large-scale algae cultivation for decarbonization, offering clean biomass processing routes, and explores sustainable production and consumption practices using microalgae, emphasizing resource recovery, recycling, and carbon-neutral approaches. Algae Biotechnology: Decarbonization, Resource Recovery, & Bioproducts provides up-to-date information on advancements in algae cultivation technologies and their potential impact on carbon mitigation, clean energy production, and green product development. The book aligns with the UN's Sustainable Development Goals related to carbon capture, clean energy, and sustainable production, and aims to educate readers on the role of microalgae in achieving energy sustainability and addressing global environmental challenges.
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Autoren/Hrsg.

Mehmood, Muhammad Aamer
Malik, Sana
Ralph, Peter J
Bose, Archishman
Betenbaugh, Micheal J

Fachgebiete

Weitere Infos & Material

Section I: Algae for decarbonization
1. Algae-based carbon capture; potential, challenges, opportunities
2. Integration of algae carbon capture with major carbon emission systems
3. Carbonomics of large-scale algae cultivation for industrial and environmental applications

Section II: Algae-based resource recovery
4: Algae-based resource recovery; potential, challenges, opportunities
5. Large-scale algae-based recycling of urban wastewater
6. Large-scale algae-based recycling of heavily contaminated wastewater
7. Integration of algae-based resource recovery with wastewater treatment systems

Section III: Bioprocessing of algal biomass to clean energy and bioproducts
8. Biotransformation of wastewater-grown algae biomass to biogas
9. Biotransformation of wastewater-grown algae biomass to liquid fuels
10. Transformation of wastewater-grown algal biomass to industrial biopolymers
11. Employing wastewater-grown biomass to reclaim the nutritional value of damaged soils
12. Algae biomass as a feedstock for biological transformation to value-added products

Section-IV: Emerging trends in Algae biotechnology
13. Algal phenomics to develop elite algae strains to meet industrial robustness
14: Algae biotechnology for global space exploration program and terraforming the planets
15. Algae-driven Industry 4.0
16. Algae-biotechnology and sustainability development goals; policy-making and global cooperation programs
17. Large-scale algae cultivation; economic, environmental, and legal aspects

Ralph, Peter J
Peter J. Ralph's research interest encompass
algae-based bioproducts include the production of food, energy, green chemistry, and bio-products using microalgae and macroalgae. Mass-scale algae cultivation to overcome commercialization barriers in the algae-based biotechnology sector. Photosynthetic efficient algae cultivation systems to produce specialty chemicals, toxins, cosmetic components, valuable oils, foods for consumption, feeds for agriculture, nutraceuticals, biologics, vaccines, and small molecules. Bioplastics - both biodegradable and durable (as a C-storage product). Advanced manufacturing linked to Industry 4.0 technology. Algal phenomics uses fully automated high-throughput screening systems. Zero waste approach to advanced biomanufacturing using biorefinery approach.

Malik, Sana
Sana Malik's research interests include the development of microalgae and cyanobacteria-based wastewater treatment technologies with concurrent production of high-value bioproducts for food, feed, and fuel applications following a Circular Economy scheme with minimum waste generation maximum resource recovery while keeping the Energy-Water-Environment nexus sustainable. I am also interested in developing carbon-neutral processes and products by harnessing the full potential of algae towards the global agenda of circular economy and net-zero carbon emissions.

Bose, Archishman
Archishman Bose's expertise and research interest lies in: Biochemical and Bioprocess Engineering, Biorefining, Circular Bioeconomy Systems, Carbon capture and utilisation, Decarbonisation, Process Design and Feasibility Assessments including techno-economic (TEA) and life cycle assessments (LCA); Sustainability Assessments. he published over 20 peer-reviewed academic journal papers (10 first author publications) and contributed to three book chapters on topics related to microalgal biogas upgrading, techno-economic feasibility and sustainability assessments of low-carbon technologies.

Mehmood, Muhammad Aamer
Professor Muhammad Aamer Mehmood's
research focuses on process optimization for the sustainable utilization of bio-resources, wastewater recycling, resource recovery, and biotransformation of biomass to bioenergy and bioproducts, including biofertilizers, industrial enzymes, and biopolymers employing microalgae/cyanobacteria/fungi as microbial cell factories in a multiproduct biorefinery paradigm. We intend to develop novel low-carbon or carbon-neutral bioprocesses for agriculture and bioindustry while keeping the energy, water, environment, and food nexus sustainable.

Betenbaugh, Micheal J
Micheal J. Betenbaugh is a professor of Chemical and Biomolecular Engineering and a lead PI of the Advanced Mammalian Biomanufacturing Innovation Center (AMBIC). He is known for integrating systems biology with cellular, metabolic, and biochemical engineering for eukaryotic biotechnology applications. He led the JHU initiative to be one of the original academic members of the National Institute for Innovation in Manufacturing Biopharmaceuticals (NIIMBL), which uses federal and industry co-funding to fine-tune existing biopharmaceutical manufacturing techniques.

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