Functionalized Cellulose Materials: Sustainable Manufacturing and Applications

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Engineering Materials Series
Functionalized Cellulose Materials: Sustainable Manufacturing and Applications
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Contents
Unveiling the Transformative Power of Smart Cellulosic Nanomaterials: Revisiting Potential Promises to Sustainable Future
	1. Introduction
	2. Cellulosic Nanomaterials Stand as a Beacon of Hope in Our Pursuit of a Sustainable Future
	3. Smart Nanomaterials: How is It a Paradigm Shift?
	4. Advanced Nanocellulosic Materials with Enhanced Strength, Durability, and Lightweight Properties
		4.1 Enhancing Cement Composites with Nano-Cellulose and Nano-Silica
		4.2 The Nanocellulosic Realm of Aerospace and Automotive Engineering
		4.3 Supercar Crafted from Cellulose Nanofibers
		4.4 Natural Filtration Capabilities of Xylem Tissue
		4.5 A Bacterial Nanocellulose Makes the Brand of Bags
		4.6 Computer Chips Using Cellulose Nanofibrils
	5. Reimagining Clean Energy
		5.1 Clean Energy: Beyond Efficiency Frontiers
		5.2 Solar Revolution 2.0
		5.3 Energy Storage Metamorphosis
	6. Conversion of Smart Nanomaterials to Achieve Sustainable Goals
		6.1 A Nanoscale Renaissance Beyond Desalination
		6.2 Bioremediation Redefined
		6.3 Smart Water Management
	7. Circular Economy: From Waste to Resource with Nanotech Muscle
		7.1 Upcycling Revolution
		7.2 Self-Healing Materials for Extended Lifespan
		7.3 Intelligent Deconstruction
		7.4 Sustainable Agriculture: Precision at the Nanoscale
		7.5 Nanobots for Targeted Delivery
		7.6 Biological Imitation for Disease and Pest-Resistant Houses
		7.7 Biocompatible Nanomaterials
		7.8 Personalized Nanomedicine
		7.9 Nanobots for Diagnostics and Therapy
	8. Conversion of Smart Nanomaterials to Achieve Sustainable Goals
		8.1 The Social Components and Ethical Approach
		8.2 Environmental, Health, and Safety Considerations
		8.3 Public Engagement and Open Dialogue
		8.4 The Ethical Landscape
	9. Conclusion
	References
Sustainable Cellulose Films as Packaging (Coating) Materials to Reduce Plastic Use
	1. Introduction
		1.1 Packaging
		1.2 Flexible Packaging
		1.3 Bio-polymer Based Films
	2. Sustainable Substitute for Packaging
		2.1 Sustainable Packaging
		2.2 Cellulose as a Solution to Plastic Pollution
	3. Modification Methods to Improve Film Functionality of Cellulose and Its Derivatives
		3.1 Physical Modification
		3.2 Chemical Modification
	4. Types of Cellulose Based Packaging Films
		4.1 Composite Films Containing Nano Crystals of Cellulose
		4.2 Cellulose Nanofibrils Based Films
	5. Fabrication Techniques of Cellulose Based Films
		5.1 Sol–Gel Technique
		5.2 ALD
	6. Applications of Cellulose Based Films
		6.1 Food Industry
		6.2 Medical Packaging
	7. Measurements for the Betterment of Sustainability
	8. Conclusion
	References
Collagen Fusion with Natural Biopolymers in Food Packaging: An In-Depth Review from Conceptualization to Consumer Application
	1. Introduction
	2. Intrinsic Properties of Collagen as a Biopolymer
	3. Collagen Based Food Packaging Films
	4. Collagen and Its Derivatives
	5. Gelatin
	6. Collagen Peptides
	7. Hydrolyzed Collagen
	8. Casting Techniques
	9. Solvent Casting Method
	10. Extrusion Method
	11. Compression Method
	12. Electrospinning Method
	13. Collagen Blended Films
		13.1 Collagen and Sodium Alginate
		13.2 Collagen and Chitosan
		13.3 Collagen and Pectin
		13.4 Collagen with Whey and Methylcellulose
		13.5 Collagen with Casein and Keratin
		13.6 Collagen with Polyhydroxyalkanoates(Pha)
	14. Applications of Collagen-Based Films
	15. Innovative Processing Techniques
		15.1 3D Printing
		15.2 High-Pressure Processing
	16. Future Prospects
	17. Conclusion
	References
Cellulose-Based Packaging: An Emerging Sustainable Packaging Option for Future Use
	1. Introduction
	2. Exploring the Versatility of Cellulose
		2.1 Morphology of Cellulose
		2.2 Understanding Various Forms of Cellulose
		2.3 Properties of Cellulose
	3. Cellulose Extraction Methods
		3.1 Physical Methods for Cellulose Extraction
		3.2 Chemical Methods for Cellulose Extraction
		3.3 Combined Mechanical and Chemical Treatments
	4. Cellulose Based Biocomposites
		4.1 Preparation of Cellulose Biocomposites
		4.2 Chemical Treatments
		4.3 Structural and Mechanical Properties
	5. Food Packaging Applications
	6. Environmental Benefits
	7. Other Cellulose Based Biocomposites
		7.1 Oil Palm Cellulose Polylactic Acid Biocomposite
		7.2 Chitosan Reinforced Nanocellulose Biocomposite
		7.3 Cellulose Alginate Biocomposite Films
		7.4 PHA Cellulose Biocomposite
	8. Various Other Applications of Cellulose-Based Biocomposites
		8.1 Medical Application
		8.2 Textiles
		8.3 Electronics
	9. Sustainability of Using Cellulose-Based Biocomposites
	10. Challenges and Future Prospects
	11. Conclusions
	References
Emerging Approaches in Hydrogen Production from Biomass
	1. Introduction
	2. Prospects of Hydrogen Energy
		2.1 Hydrogen Production Methods
		2.2 Hydrogen from Biomass Based Feedstocks
		2.3 Challenges in Hydrogen Production
	3. Emerging Techniques in Hydrogen Production via Pyrolysis
		3.1 Anaerobic Digestion Combined Pyrolysis
		3.2 Integrated Pyrolysis and Gasification
		3.3 Pyrolysis in Bifunctional Catalyst-Sorbent
	4. Conclusions
	References
Comparative Analysis of Nanomaterials and Artificial Intelligence for Sustainable Nutrient Management in Soil
	1. Introduction
		1.1 Importance of Soil Nutrients for Plant Growth
		1.2 Challenges of Conventional Nutrient Management Practices
		1.3 The Rise of Precision Agriculture: Towards Sustainable Solutions
	2. Nanomaterials for Sustainable Nutrient Management
		2.1 Characteristics and Properties of Nanomaterials Relevant to Soil Nutrient Management
		2.2 Applications of Nanomaterials in Enhancing Nutrient Uptake and Delivery in Soil
		2.3 Environmental Considerations and Potential Risks Associated with Nanomaterial Use in Agriculture
		2.4 Nano-Soil Amendments
	3. Artificial Intelligence in Soil Nutrient Management
		3.1 Predictive Analytics
		3.2 Machine Learning Models
		3.3 AI-Driven Soil Testing
		3.4 AI for Nutrient Management Recommendations
	4. Comparative Analysis
	5. Integration of Nanotechnology and AI
		5.1 Potential Benefits of Integrating Nanomaterials and AI
	6. Conclusion
	References
Biocompatible Cellulose Derivatives: Green Chemistry and Its Sustainable Applications
	1. Introduction
		1.1 Attributes of Cellulose
		1.2 Limitations of Natural Cellulose
		1.3 Functionalized Cellulose
	2. Functionalization and Manufacturing of Cellulose Materials
		2.1 Mineralization of Cellulose
		2.2 Chemical Functionalization of Cellulose
		2.3 Unconventional Methods in Cellulose Functionalization
	3. Sustainable Production of Cellulose, and Its Derivatives
		3.1 Methodology
	4. Challenges Faced
		4.1 Limited Functionality Due to the Chemical Nature
		4.2 Technical, Economic, and Sustainability Issues
	5. Diverse Applications of Functionalized Cellulose
		5.1 Utilization of Cellulose in Biomedical Applications
		5.2 Utilization of Functionalized Cellulose Materials to Sensors
		5.3 Green Synthesis Routes for Nanoparticles and Catalysis
		5.4 Wastewater Management Using Functionalized Cellulose
		5.5 Development of Polymers Using Functionalized Cellulose
	6. Environmental Impact
		6.1 Derivation of Cellulose Materials: Selective Oxidation
		6.2 Hazards Due to Poor Thermal Stability
	7. Economic Viability of Functionalized Cellulose
	8. Future Scope
		8.1 Obtaining Favourable Properties with Sustainable Modifications
		8.2 Enhancement in Smart Electronics
		8.3 Research and Development to Broaden the Viability of Cellulose Material Production
	9. Conclusion
	References
Cellulose and Chitosan-Based Bionanocomposites in Biomedical Applications
	1. Introduction
	2. Cellulose
		2.1 Cellulose Based Biocomposites
		2.2 Cellulose Based Composites for Antibacterial Applications
		2.3 Cellulose–Inorganic Nanoparticles Bionanocomposites for Antibacterial Applications
		2.4 Cellulose Based Bionanocomposites for Wound Dressing
		2.5 Cellulose Based Bionanocomposites in Drug and Gene Delivery
		2.6 Cellulose Based Bionanocomposites in Scaffolds for Bone, Skin, and Tissue Engineering
	3. Chitosan
		3.1 Chitosan Based Bionanocomposites in Biomedical Applications
		3.2 Chitosan-Nanoclay Bionanocomposite in Drug Delivery
		3.3 Chitosan-Magnetic Nanoparticle Bionanocomposites in Drug Delivery
		3.4 Chitosan-Carbon Nanostructures Bionanocomposite in Drug Delivery
	4. Conclusions
	References
Turning Cigarette Butts (CBs) into Valuable Resources: Technical Potential and Drawbacks
	1. Introduction
	2. Methodology
	3. Results and Discussion
		3.1 Composition of Cigarette Butts
		3.2 Pollutants in Cigarette Butts
		3.3 Toxicity of Cigarette Butts (CBs)
		3.4 Research on Valorization of Cigarette Butts
	4. Conclusion and Future Perspectives
	5. Declaration of Competing Interest
	References
Conversion of Smart Nanomaterials to Achieve Sustainable Goals
	1. Introduction
	2. Nano Materials for Sustainable Agriculture (UNSDG 2)
		2.1 Nano Fertilizers and Their Impact on Crop Yield
		2.2 Nanosensors for Precision Agriculture
		2.3 Nano Pesticides
		2.4 Nano Materials for Pest and Disease Management
	3. Nano Materials for Health and Well-Being (UNSDG 3)
		3.1 Nano Medicine and Drug Delivery Systems
		3.2 Diagnostic Applications of Nano Materials
		3.3 Nano-Enabled Therapies for Various Diseases
	4. Nano Materials for Quality Education (UNSDG 4)
	5. Nano Materials for Clean Water and Sanitation (UNSDG 6)
		5.1 Nanotechnology Applications in Water Purification
		5.2 Nano Materials for Wastewater Treatment
		5.3 Nano Sensors for Water Quality Monitoring
	6. Nano Materials for Affordable and Clean Energy (UNSDG 7)
		6.1 Nano Materials in Solar Energy Harassing
		6.2 Nanostructured Materials for Energy Storage
	7. Nano Materials for Sustainable Cities and Communities (UNSDG 11)
		7.1 Nano Materials for Pollution Control
		7.2 Smart Nanomaterials for Infrastructure Design and Development
	8. Nano Materials for Responsible Consumption and Production (UNSDG 12)
		8.1 Nanotechnology in Waste Management
		8.2 Sustainable Nanomaterial Production Processes
	9. Nano Materials for Climate Action (UNSDG 13)
		9.1 Nanotechnology in Capturing of Carbon and Its Storage for Greenhouse Gas Reduction
	10. Conclusion
	References
Smart Sustainable Materials: A Blueprint for a Better Tomorrow
	1. Introduction
	2. Revolutionising Healthcare with a Green Touch
		2.1 Biocompatible Implant and Tissue Engineering
		2.2 Targeted Drug Delivery with Smart Polymers
		2.3 Biosensors and Wearables for Real-Time Monitoring:
		2.4 Biodegradable Medical Packaging and Devices
	3. A Natural Glow: Up for the Cosmetic Industry
		3.1 Biodegradable Packaging
		3.2 Natural and Organic Ingredients
		3.3 Biodegradable and Refillable Products
		3.4 Microfiber Free Formula
		3.5 Bio Based Bottles from Algae
		3.6 Compostable Packaging from Wheat Straw
		3.7 Reusable Silicone Moulds for Makeup Palettes
	4. Revolutionising the Food Industry
	5. Textile and Clothing Industry
		5.1 Traditional Materials and Their Drawbacks
		5.2 Solution: Sustainable Materials
	6. Pharmaceutical and Biomedical Avenues
		6.1 Self-Healing Hydrogels for Drug Delivery: Self-Healing Hydrogels for Drug Delivery
		6.2 Stimuli-Responsive Nanoparticles for Targeted Therapy: Stimuli-Responsive Nanoparticles for Targeted Therapy
		6.3 Biomimetic Nanorobots for Targeted Drug Delivery and Surgery
	7. Sustainable Materials: Revolutionising the Tech World
		7.1 Environmental Benefits
		7.2 Safety and Health Benefits
		7.3 Economic Benefits
	8. Construction Industry and Sustainable Materials
		8.1 Environmental Benefits
		8.2 Economic Benefits
	9. Education and Awareness: The Cornerstone of a Sustainable Material Future
		9.1 Knowledge Gaps and the Need for Education
		9.2 Plans for Effective Education and Awareness Campaigns
		9.3 Current Scenario and Emerging Initiatives
	10. Conclusion
	References:
Game Changer: How Cellulose-Based Bioleather is Transforming the Market
	1. Introduction
	2. Challenges with Traditional Leather and Its Emerging Cellulosic Correctives
	3. Cellulose: A Promising Material for Bioleather
	4. Cellulosic Sources
		4.1 Plant-Based Sources
		4.2 Microbial Bioleather: A Frontier in Sustainable Materials
	5. Conclusions
	References