Advances in nanotechnology for marine antifouling /

Advances in Nanotechnology for Marine Antifouling surveys the latest research in the application of nanotechnology for biofouling inhibition. The book gathers in-depth information on the various micro and nano-techniques, nanocoatings, polymeric composites paints, methods of application and preventi...

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Bibliographic Details
Corporate Author:	ScienceDirect (Online service)
Other Authors:	Gupta, Ram K. (Editor), Kumar, Ashok (Professor of microbial biotechnology) (Editor), Nguyen, Tuan Anh (Chemist) (Editor), Sharma, Swati, Dr (Editor), Bilal, Muhammad (Professor of bioengineering) (Editor)
Format:	eBook
Language:	English
Published:	Amsterdam : Elsevier, 2023.
Subjects:	Paint, Antifouling > Technological innovations. Nanotechnology > Technological innovations. Peinture antisalissure > Innovations. Nanotechnologie > Innovations. Electronic books.
Online Access:	Connect to the full text of this electronic book

Table of Contents:

Front Cover
Advances in Nanotechnology for Marine Antifouling
Advances in Nanotechnology for Marine Antifouling
Copyright
Contents
Contributors
1
Biofouling: current status and challenges
1.1 Introduction
1.2 Microbiology and biofouling
1.2.1 Historical background
1.3 Classification of biofouling
1.3.1 Microbiofouling
1.3.2 Macrobiofouling
1.4 Steps of biofouling
1.5 Factors affecting biofouling
1.5.1 Temperature
1.5.2 pH
1.5.3 Oxygen supply
1.5.4 Divergence of species
1.5.5 Sunlight
1.6 Industries and biofouling
1.6.1 Shipping industry
1.6.2 Medical industry
1.6.3 Power industry
1.6.4 Automobile industry
1.6.5 Plastics industry
1.6.6 Nutrition industry
1.7 Need of the hour
1.8 Conclusions
References
2
Bioinspired antifouling coatings with topographies
2.1 Introduction
2.1.1 Marine biofouling
2.1.2 Biofouling mechanisms
2.1.3 Conventional antifouling strategies
2.1.4 Modern bioinspired strategies
2.2 Bioinspired antifouling coatings with topographies
2.2.1 Coatings with micro- and nanostructured topographies
2.2.1.1 Antifouling mechanisms of micro- and nanostructured surfaces
2.2.1.2 Bioinspired micro- and nanostructured coatings for combating biofouling
Lotus-inspired coatings
Shark-inspired coatings
Shell-inspired coatings
Mangrove-inspired coatings
2.2.2 Coatings with macroscopic topographies
2.2.2.1 Coatings inspired by terrestrial organisms
2.2.2.2 Coatings inspired by marine organisms
2.3 Conclusion
References
3
Bionic marine antifouling coating
3.1 Introduction
3.2 Biofouling
3.2.1 Fouling process
3.2.2 Main antifouling strategies
3.3 Bionic antifouling strategy
3.3.1 Natural antifouling agent
3.3.1.1 Antifouling agents derived from marine organisms.
3.3.1.2 Antifouling agents derived from terrestrial organisms
3.3.2 Antibacterial coating of quaternary ammonium salt-guanidine compound
3.3.3 Self-polishing antifouling coating
3.3.4 Photocatalytic antibacterial coating
3.3.5 Antimicrobial peptides
3.4 Bionic fouling release strategy
3.4.1 Low-surface energy surface (organic fluorine/silicone)
3.4.1.1 Silicone coating
3.4.1.2 Organic fluorine coating
3.4.2 Superhydrophobic self-cleaning surface
3.4.3 Hydrophilic surface
3.4.4 Amphipathic surface
3.4.5 Bionic surface with microstructure
3.4.6 Microphase separation structure surface
3.4.7 Bionic slippery liquid-infused surface
3.4.8 Bionic fluorescent coating
3.5 Other bionic strategies
3.5.1 Electrocatalytic antifouling
3.6 Summary and outlook
References
4
Zwitterionic antifouling coating
4.1 Introduction
4.2 Chemical structure
4.3 Preparation of zwitterionic antifouling coatings
4.3.1 Monomeric zwitterionic antifouling coatings
4.3.2 Polymeric zwitterionic antifouling coatings
4.3.3 Zwitterion-based amphiphilic antifouling coatings
4.3.4 Degradable zwitterionic coatings
4.3.5 Other strategies
References
5
Beyond the marine antifouling activity: the environmental fate of commercial biocides and other antifouling age ...
5.1 Introduction
5.2 Physicochemical properties
5.2.1 Water solubility
5.2.2 Octanol-water partition
5.2.3 Vapor pressure
5.3 Environmental fate properties
5.3.1 Sediment-water partition
5.3.2 Bioconcentration factor
5.4 Leaching and release rate
5.5 Persistence
5.5.1 Hydrolysis
5.5.2 Photolysis
5.5.3 Biodegradation
5.5.4 Identification of transformation products and pathways
5.6 Ecotoxicity assessment
5.7 Conclusion
Funding
References.
6
Ceramic polymer nanocomposites as eco-friendly marine antifouling coatings
6.1 Introduction
6.2 Marine fouling organisms
6.3 Costs of marine biofouling
6.4 Antifouling coating methods
6.5 Nonstick fouling-release coating approach
6.5.1 Fluoropolymeric fouling-release coatings
6.5.2 Silicone-based fouling-release coatings
6.6 Biomimetic antifouling methods
6.6.1 Superhydrophobicity in nature
6.6.2 Characterization of superhydrophobic surfaces
6.7 Advanced fouling-release and self-cleaning nanocomposite coatings
6.7.1 Silicone reinforced with ceramic nanofillers
6.7.2 Silicone-graphene-ceramic nanocomposites
6.8 Conclusions
References
7
Biodiversity of deep ocean on development of biofilms: Biofouling communities and corrosion performance of mate ...
7.1 Introduction
7.2 Variations in temperature, pressure, and oxygen with depth and their influence on biodiversity
7.3 Ocean microbiome and metagenomics of deep-sea planktonic and biofilm communities
7.4 Hydrothermal vent ecosystem
7.5 Cold seep/knoll and continental slope ecosystem
7.6 Seamount ecosystems
7.7 Corrosion performance of metals and alloys in deep-sea environment
7.8 Conclusions
References
8
Biofouling in the petroleum industry
8.1 Introduction
8.2 Field development and petroleum infrastructure
8.2.1 Upstream structures
8.2.2 Midstream and downstream equipment
8.3 Biofilm formation
8.3.1 Facilitating conditions
8.3.1.1 Temperature of seawater
8.3.1.2 Seawater zone
8.3.1.3 Currents and distance to shore
8.3.1.4 Substrata
8.3.2 Communication among microorganisms
8.4 Macrobiofoulers
8.5 Oil reservoirs and microorganisms
8.5.1 Microbial communities in oil reservoirs
8.5.1.1 Sulfate-reducing bacteria
8.5.1.2 Fermentative ARBs
8.5.2 Bioclogging in oil reservoirs.
8.5.3 Produced water
8.6 Midstream and downstream
8.6.1 Pipelines
8.6.2 Fuel tanks
8.6.3 Risk assessment and monitoring structural biofouling
8.7 Conventional biofouling treatment process
8.8 Conclusion
References
9
Polymer/graphene-derived nanocomposites as advanced marine antifouling coatings
9.1 Introduction
9.2 Developing of maritime fouling
9.3 Graphene and graphene-based materials
9.4 Synthesis of graphene materials
9.4.1 Exfoliation and mechanical cleavage
9.4.2 Chemical exfoliation
9.4.3 Chemical vapor deposition
9.5 Graphene-derived nanocomposites
9.6 Graphene materials are used to create superhydrophobic surfaces
9.6.1 Solution casting method
9.6.2 Melt-blending method
9.6.3 In situ polymerization method
9.6.4 Electrospinning
9.6.5 Electrodeposition
9.7 Polymer-graphene materials and their interactions
9.8 Graphene-based nanocomposites for fouling-release coatings
9.9 Conclusions and outlooks
References
10
Nanoparticles as an exotic antibacterial, antifungal, and antiviral agents
10.1 Introduction
10.2 Metal-based nanomaterials
10.2.1 Gold nanoparticles
10.2.2 Silver nanoparticles
10.2.2.1 Mechanism of antiviral and antimicrobial activity
10.2.2.2 Silver v SARS-CoV-2
10.2.2.3 Food packaging
10.2.3 Other metallic nanoparticles
10.3 Metal oxide-based nanomaterials
10.3.1 Disinfection of SARS-CoV-2 by metal oxides
10.3.2 Metal oxide nanoparticles in textiles
10.3.3 Metal oxide nanoparticles for food packaging
10.4 Carbon-based nanomaterials
10.4.1 Graphene and its derivatives
10.4.2 Fullerene
10.4.2.1 Antiviral mechanism of fullerene
10.4.2.2 Antimicrobial mechanism of fullerene
10.4.3 Polymeric nanomaterials
10.5 Conclusion
Acknowledgments
References.
11
Nanomaterial-based smart coatings for antibacterial, antifungal, and antiviral activities
11.1 Introduction
11.2 Strategies for antimicrobial surfaces
11.2.1 Contact-killing coatings
11.2.2 Antiadhesion/microbial repelling coatings
11.2.3 Release-based coatings
11.2.4 Multifunctional coatings
11.3 Nanomaterials in antimicrobial and antiviral smart coating
11.3.1 Inorganic nanomaterials
11.3.2 Organic nanomaterials
11.4 Application of nanomaterial-based antimicrobial and antiviral smart coatings
11.4.1 Medical devices
11.4.2 Health care facilities
11.4.3 Textiles
11.4.4 Food packaging
11.4.5 Industrial equipment
11.5 Challenges and future perspectives
11.6 Conclusion
References
12
Polymeric antibacterial, antifungal, and antiviral coatings
12.1 Introduction
12.2 Antimicrobial polymer coatings
12.3 Antimicrobial biopolymer coatings
12.4 Protein-based antimicrobial surfaces
12.5 Metal-based coating as antimicrobial disinfectant
12.6 Mode of action in antimicrobial polymer coatings
12.7 Applications
12.7.1 Applications of antibacterial polymeric coatings
12.7.2 Applications of antifungal polymeric coatings
12.7.3 Applications of antiviral coatings
12.8 Challenges
12.9 Safety concerns and risk mitigation
12.10 Conclusion and future outlook
References
13
Antifouling mechanisms in and beyond nature: leverages in realization of bioinspired biomimetic antifouling co ...
13.1 Introduction
13.2 Biofouling in the marine environment
13.3 Wettability concepts
13.4 Developments in polymeric antifouling coatings
13.5 Natural superhydrophobic surfaces and mechanisms of bioinspired wettability
13.6 Effect of topographies and textures and biomimetic approaches investigated
13.7 Self-cleaning surfaces.