Kooperativer Bibliotheksverbund

UID:

Format: 1 online resource (569 pages)

ISBN: 0-323-98400-2

Content: Advanced Applications of Ionic Liquids discusses the intersection of nanotechnology with ionic liquids (ILs) and materials, along with opportunities for advanced engineering applications in various research fields. Novel materials at nano scales with ILs creates an upsurge in the thermal and electrochemical constancy of the nano scale particles, making them ideal for industrial applications. The implementation of ILs at nano scale includes an interaction of constituents, which is beneficial for electron transfer reactions. These new composites can be implemented as sensors, electronics, catalysts and photonics. Including ILs in polymer composites enhance electrochemical consistency, govern particle size, upsurge conductivity, reduce toxicity, and more.

Note: Front Cover -- Advanced Applications of Ionic Liquids -- Copyright Page -- Dedication -- Contents -- List of contributors -- About the editors -- Preface -- 1 Catalysis and electrochemistry -- 1 Progressions in ionic liquid-based electrochemical research -- 1.1 Introduction -- 1.2 Physical properties of ionic liquids -- 1.2.1 Conductivity -- 1.2.2 Viscosity -- 1.2.3 Electrochemical potential window -- 1.3 Electrochemical properties -- 1.4 Applications of ionic liquids in electrochemistry -- 1.4.1 Electrochemical sensors -- 1.4.2 Electrodeposition -- 1.4.3 Electroredox -- 1.4.4 Electrochemical biosensors -- 1.4.5 Applications of ionic liquids in Li-ion batteries -- 1.4.6 Applications of ionic liquids for supercapacitors -- 1.4.7 Applications of ionic liquids in electropolymerization -- 1.5 Conclusion -- References -- 2 Recapitulation on the separation and purification of biomolecules using ionic liquid-based aqueous biphasic systems -- 2.1 Introduction -- 2.2 Applications of ionic liquids-based aqueous biphasic system in separation and purification of biomolecules -- 2.2.1 Amino acids -- 2.2.2 Proteins -- 2.2.3 Enzymes -- 2.2.4 Nucleic acids -- 2.3 Conclusion -- Acknowledgments -- Nomenclature -- Abbreviations -- Ionic Liquids and Good Buffers -- Proteins -- Enzymes -- Salts -- Acid -- References -- 3 Current trends and applications of ionic liquids in electrochemical devices -- 3.1 Introduction -- 3.1.1 History of ionic liquids in electrochemical devices -- 3.2 Ionic liquids in energy storage devices and conversion materials -- 3.3 Ionic liquid in energy sustainability and CO2 sequestration -- 3.4 Ionic liquids as a novel electrolyte medium for advanced electrochemical devices -- 3.5 Ionic liquids' electrochemical sensing properties -- 3.6 Applications of room-temperature ionic liquids. , 3.6.1 Electrochemical applications of room-temperature ionic liquids -- 3.6.2 Room-temperature ionic liquid as a nonfaradaic biosensing component -- 3.6.3 Room-temperature ionic liquids in electrochemical gas sensoring -- 3.7 Ammonium, pyrrolidinium, phosphonium, and sulfonium-based ionic liquids and electrochemical properties -- 3.8 Current and future prospects -- 3.8.1 Ionic liquids as electrolytes -- 3.8.2 Ionic liquids as lubricants and hydraulic fluids -- 3.8.3 Ionic liquids as chemical production processes -- 3.8.4 Ionic liquids as hydrogen storage -- 3.9 Conclusions -- References -- 4 Green chemistry of ionic liquids in surface electrochemistry -- 4.1 Introduction -- 4.1.1 Important characteristics of electrochemical reactions -- 4.1.1.1 Electrochemical current and potential -- 4.1.1.2 Electrochemical interfaces -- 4.1.1.3 Models of electrochemical electron transfer -- 4.1.2 Electrochemistry at the molecular scale -- 4.1.2.1 Surface structure -- 4.1.2.2 Bonding of ions -- 4.1.2.3 Bonding of water -- 4.1.2.4 Experimental aspects of current/voltage properties -- 4.1.3 Ionic liquids properties pertinent to surface electrochemistry -- 4.2 Role of ionic liquids in surface electrochemistry -- 4.2.1 Carbon ionic liquid electrode -- 4.2.1.1 Direct electrochemistry of hemoglobin -- 4.2.1.2 Determination of various substances -- 4.2.2 Quartz crystal microbalance -- 4.2.3 Chemical warfare agent -- 4.2.4 Electrochemical oxidation -- 4.3 Conclusions -- References -- 5 An evolution in electrochemical and chemical synthesis applications in prospects of ionic liquids -- 5.1 Introduction -- 5.2 Electrochemical oxidation reactions using room-temperature ionic liquids -- 5.2.1 Oxidative self-coupling reaction -- 5.2.2 Shono oxidation of carbamates -- 5.2.3 Oxidation of alcohols -- 5.2.4 Bromination reaction. , 5.3 Electrochemical reduction reactions using room-temperature ionic liquid -- 5.3.1 Electroreductive coupling of organic halides -- 5.3.2 Pinacol coupling reaction -- 5.3.3 Electrochemical reduction of carbon dioxide gas -- 5.3.4 Electrocarboxylation reaction -- 5.3.5 Synthesis of aryl zinc compounds -- 5.3.6 Electrochemical reductive coupling to form 1,6-diketone -- 5.3.7 Electrochemical reduction of benzoyl chloride -- 5.3.8 Organocatalysis using electrogenerated bases -- 5.4 Electrochemical polymerization reactions using room-temperature ionic liquids -- 5.5 Electrochemical partial fluorination using room-temperature ionic liquids -- 5.5.1 Anodic fluorination of dithioacetals -- 5.5.2 Electrochemical fluorination utilizing mediators -- 5.5.3 Fluorination of methyl adamantane-1-carboxylate electrochemically -- 5.6 Other electrochemical reactions using room-temperature ionic liquids -- 5.6.1 Electrogenerated N-heterocyclic carbenes -- 5.6.1.1 Synthesis of β-lactams -- 5.6.1.2 Henry reaction -- 5.6.1.3 Benzoin condensation -- 5.6.1.4 Stetter reaction -- 5.6.1.5 Staudinger reaction -- 5.6.1.6 Preparation of γ-butyrolactones -- 5.6.1.7 Esterification reaction -- 5.6.1.8 Transesterification -- 5.6.1.9 Oxidative esterification of aromatic aldehydes -- 5.6.1.10 Preparation of N-acyloxazolidin-2-ones -- 5.6.1.11 N-Functionalisation of benzoxazolones -- 5.6.2 Functionalisation of nitroaromatic compounds -- 5.6.3 Epoxidation reaction using room-temperature ionic liquids -- 5.7 Conclusions -- Abbreviations -- References -- 6 Recent changes in the synthesis of ionic liquids based on inorganic nanocomposites and their applications -- 6.1 Introduction -- 6.1.1 Inorganic nanocomposite materials-an overview -- 6.1.2 Development of inorganic nanocomposite materials synthesis -- 6.1.3 Role of ionic liquid in the synthesis of inorganic nanocomposite. , 6.1.4 Application-based importance of ionic liquids in inorganic nanocomposite -- 6.2 Synthesis of inorganic nanocomposite materials using ionic liquid -- 6.2.1 Sol-gel method -- 6.2.2 Hydrothermal method -- 6.2.3 Microemulsion method -- 6.2.4 Precipitation and co-precipitation method -- 6.2.5 Rays mediated method -- 6.2.5.1 Photochemical method -- 6.2.5.2 Photocatalytic deposition -- 6.2.5.3 Sonochemical method -- 6.2.6 Electrochemical method -- 6.3 How organic-inorganic is different from inorganic nanocomposites? -- 6.4 Recent advancements and advantages of inorganic nanocomposites with ionic liquids -- 6.4.1 Storage of heat energy -- 6.4.1.1 Advantages -- 6.4.2 Electrolytic support -- 6.4.2.1 Advantages -- 6.4.3 Solvents improvement -- 6.4.3.1 Advantages -- 6.4.4 Analytics and purity -- 6.4.4.1 Advantages -- 6.4.5 Additives -- 6.4.5.1 Advantages -- 6.5 Current applications and their future perspective -- 6.5.1 Biomedical -- 6.5.2 Environmental science -- 6.5.2.1 Water treatment -- 6.5.2.2 Soil treatment -- 6.5.2.3 Air pollution treatment -- 6.5.3 Nuclear science -- 6.5.4 Food science -- 6.5.5 Energy storage and transfer -- 6.5.6 Catalysis -- 6.5.7 Lubricants -- 6.5.8 Sensors -- 6.5.9 Electrochemistry -- 6.6 Reaction mechanism of ionic liquids-based synthesized nanocomposite materials -- 6.7 Conclusions -- Abbreviations -- Author contributions -- Conflicts of interest -- References -- 7 Ionic liquids as green and efficient corrosion-protective materials for metals and alloys -- 7.1 Introduction -- 7.1.1 Effect of corrosion -- 7.1.2 Causes of corrosion -- 7.1.3 Techniques of corrosion protection -- 7.1.4 Ionic liquids as green corrosion protectors -- 7.1.5 Applications of ionic liquids -- 7.1.6 Classification of ionic liquids -- 7.2 Ionic liquids as corrosion protector for metals and alloy. , 7.2.1 Ionic liquids as corrosion protector for iron and alloy -- 7.2.2 Ionic liquids as corrosion protector for Al -- 7.2.3 Ionic liquids as corrosion protector for Cu and Zn -- 7.3 Corrosion protection mechanism -- 7.4 Conclusions and future perspectives -- References -- 2 Separation technology -- 8 Ionic liquids as valuable assets in extraction techniques -- 8.1 Introduction -- 8.2 Ionic liquids -- 8.3 Ionic liquids for the extraction of natural products from the plants -- 8.3.1 Ultrasonic-assisted ionic liquid approach for the extraction of natural products -- 8.3.2 Microwave-assisted ionic liquid approach for the extraction of natural products -- 8.3.3 Reactive dissolution of biomass in ionic liquids for the extraction of natural products -- 8.4 Ionic liquids in extraction of pharmaceuticals from biological and environmental samples -- 8.5 Ionic liquids for the extraction of contaminants from wastewater -- 8.5.1 Extraction of toxic metal ions -- 8.5.2 Extraction of organic pollutants -- 8.6 Ionic liquids for the extraction of soil contaminants and soil organic matter -- 8.6.1 Extraction of soil contaminants -- 8.6.1.1 Extraction of soil organic pollutants -- 8.6.1.2 Extraction of soil heavy metal ions -- 8.6.2 Extractions of soil organic matter -- 8.7 Extraction of rare earth metals -- 8.8 Ionic liquids for the extraction of food contaminants -- 8.9 Applications of ionic liquids -- 8.10 Conclusion and future prospective -- Acknowledgments -- References -- 9 An involvement of ionic liquids and other small molecules as promising corrosion inhibitors in recent advancement of tech... -- 9.1 Consequences of corrosion -- 9.2 Economic effects -- 9.3 Methods to control corrosion -- 9.3.1 Material selection -- 9.3.2 Coating -- 9.3.2.1 Metallic coating -- 9.3.2.2 Organic coating -- 9.3.2.3 Inorganic coatings -- 9.4 Inhibitors -- 9.5 Anodization -- 9.6 Cathodic protection.

Additional Edition: Print version: Siddique, Jamal Akhter Advanced Applications of Ionic Liquids San Diego : Elsevier,c2022 ISBN 9780323999212

Language: English

UID:

Format: 1 online resource (398 pages)

ISBN: 0-12-820898-8

Content: "Advances in Aerogel Composites for Environmental Remediation presents both contextual information about aerogels, from common to advanced aerogels, natural to synthetic, along with details about its application in environmental remediation. The book addresses common day-to-day environmental problems and solutions using natural and synthetic aerogel materials. It discusses fabrication of various aerogel composites and their design and applications towards different environmental remediation technologies and compares the properties and advantages of aerogels in contrast to traditional materials. Given the consistent increase in environmental pollution, the need to explore new materials and advances in remediation technology is becoming more urgent. This valuable resource brings researchers and practitioners in environmental remediation and environmental science and engineering to the forefront of remediation technologies with a thorough understanding of the benefits of and techniques used in relation to aerogel composites"--

Note: Aerogel and its composites: fabrication and properties / Mohammad Omaish Ansari [and 4 others] -- Natural aerogels for pollutant removal / Sandeep R. Kurundawade [and 3 others] -- Biomedical applications of aerogel / Varish Ahmad [and 6 others].

Additional Edition: ISBN 0-12-820732-9

Language: English

UID:

Format: 1 online resource

ISBN: 9783527807918 , 3527807918 , 9783527807901 , 352780790X

Content: "A comprehensive and up-to-date overview of the latest research trends in conductive polymers and polymer hybrids, summarizing recent achievements. The book begins by introducing conductive polymer materials and their classification, while subsequent chapters discuss the various syntheses, resulting properties and up-scaling as well as the important applications in biomedical and biotechnological fields, including biosensors and biodevices. The whole is rounded off by a look at future technological advances. The result is a well-structured, essential reference for beginners as well as experienced researchers."--

Note: Bioinspired Polydopamine and Composites for Biomedical Applications / Ziyauddin Khan, Ravi Shanker, Dooseung Um, Amit Jaiswal, Hyunhyub Ko -- Multifunctional Polymer-Dilute Magnetic Conductor and Bio-Devices / Imran Khan, Weqar A Siddiqui, Shahid P Ansari, Shakeel khan, Mohammad Mujahid Ali khan, Anish Khan, Salem A Hamid -- Polymer-Inorganic Nanocomposite and Biosensors / Anish Khan, Aftab Aslam Parwaz Khan, Abdullah M Asiri, Salman A Khan, Imran Khan, Mohammad Mujahid Ali Khan -- Carbon Nanomaterial-Based Conducting Polymer Composites for Biosensing Applications / Mohammad O Ansari -- Graphene and Graphene Oxide Polymer Composite for Biosensors Applications / Aftab Aslam Parwaz Khan, Anish Khan, Abdullah M Asiri -- Polyaniline Nanocomposite Materials for Biosensor Designing / Mohammad Oves, Mohammad Shahadat, Shakeel A Ansari, Mohammad Aslam, Iqbal IM Ismail -- Recent Advances in Chitosan-Based Films for Novel Biosensor / Akil Ahmad, Jamal A Siddique, Siti H M Setapar, David Lokhat, Ajij Golandaj, Deresh Ramjugernath -- Self Healing Materials and Conductivity / Jamal A Siddique, Akil Ahmad, Ayaz Mohd -- Electrical Conductivity and Biological Efficacy of Ethyl Cellulose and Polyaniline-Based Composites / Faruq Mohammad, Tanvir Arfin, Naheed Saba, Mohammad Jawaid, Hamad A Al-Lohedan -- Synthesis of Polyaniline-Based Nanocomposite Materials and Their Biomedical Applications / Mohammad Shahadat, Shaikh Z Ahammad, Syed A Wazed, Suzylawati Ismail -- Electrically Conductive Polymers and Composites for Biomedical Applications / Haryanto, Mohammad Mansoob Khan.

Language: English

Keywords: Electronic books. ; Electronic books. ; Electronic books.

DOI: 10.1002/9783527807918

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9783527807918

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9783527807918

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9783527807918

UID:

Format: xvii, 243 Seiten : , Illustrationen, Diagramme (teilweise farbig).

ISBN: 978-3-527-34289-1

Additional Edition: Erscheint auch als Online-Ausgabe, ePDF ISBN 978-3-527-80790-1

Additional Edition: Erscheint auch als Online-Ausgabe, ePub ISBN 978-3-527-80792-5

Additional Edition: Erscheint auch als Online-Ausgabe, Mobi ISBN 978-3-527-80793-2

Additional Edition: Erscheint auch als Online-Ausgabe, oBook ISBN 978-3-527-80791-8

Language: English

Subjects: Engineering , Chemistry/Pharmacy , Physics

Keywords: Leitfähige Polymere

Author information: Khan, Anish.

UID:

Format: 1 online resource (604 pages)

ISBN: 9780323912068

Content: Advances in Electronic Materials for Clean Energy Conversion and Storage Applications reviews green synthesis and fabrication techniques of various electronic materials and their derivatives for applications in photovoltaics. The book investigates recent advances, progress and issues of photovoltaic-based research, including organic, hybrid, dye-sensitized, polymer, and quantum dot-based solar cells. There is a focus on applications for clean energy and storage in the book. Clean energy is defined as energy derived from renewable resources or zero-emission sources and natural processes that are regenerative and sustainable resources such as biomass, geothermal energy, hydropower, solar and wind energy. Materials discussed include nanomaterials, nanocomposites, polymers, and polymer-composites. Advances in clean energy conversion and energy storage devices are also reviewed thoroughly based on recent research and developments such as supercapacitors, batteries etc. Reliable methods to characterize and analyze these materials systems and devices are emphasized throughout the book. Important information on synthesis and analytical chemistry of these important systems are reviewed, but also material science methods to investigate optical properties of carbon-nanomaterials, metal oxide nanomaterials and their nanocomposites. Reviews the latest advances in electronic materials synthesis, fabrication and application in energy Discusses green, cost-effective, simple and large-scale production of electronic materials Includes critical materials and device characterization techniques that enhance our understanding of materials' properties and measure device performance.

Note: Part I: Advanced electronic materials for solar energy applications -- 1. Introduction to advanced electronic materials for solar energy applications -- 2. Advanced electronic materials for engineering energy applications -- 3. Carbon-based nanomaterials for solar energy -- 4. Quantum dots/Nanoparticles for solar energy -- 5. Organic semiconducting materials for solar energy -- 6. Small molecule organic solar cells -- 7. Polymer Organic Solar Cells -- 8. Metal halide hybrid perovskite materials for solar energy -- 9. Metal-halide perovskite nanomaterials and applications -- 10. Metal-halide perovskites for hybrid solar cells -- 11. Photon-downconversion materials for solar energy -- 12. Quantum dot as photon-downconversion materials -- 13. Organic dyes as photon-downconversion materials -- 14. Polymer-based nanocomposite for solar energy applications -- 15. Prospects and future perspective of electronic materials for solar cell applications -- Part II. Advanced electronic materials for energy storage (supercapacitor and battery) applications -- 16. Introduction to advanced electronic materials for energy storage applications -- 17. Advanced electronic materials for engineering energy storage applications -- 18. Carbon-based nanomaterials for supercapacitor electrode materials -- 19. Transition metal oxide nanomaterials as electrodes for supercapacitor applications -- 20. Transition metal oxides as electrode materials -- 21. Graphene derivative/transition metal oxides nanocomposites as electrode materials -- 22. Polymers-based nanocomposite as electrode materials for supercapacitor applications -- 23. Transition metal oxide nanomaterials-based electrodes for battery applications -- 24. Carbon-based nanomaterials for battery applications -- 25. Graphene-derivative decorated transition-metal oxide nanocomposites for battery applications -- 26. Prospects and future perspective of nanomaterials for energy storage applications.

Language: English

UID:

Format: xvii, 586 Seiten : , Illustrationen.

ISBN: 978-0-323-91206-8

Series Statement: Woodhead Publishing series in electronic and optical materials

Additional Edition: Erscheint auch als Online-Ausgabe ISBN 978-0-323-91447-5

Language: English

Keywords: Aufsatzsammlung

UID:

Format: 1 online resource (606 pages)

ISBN: 9780323914475 , 9780323912068

Series Statement: Woodhead Publishing Series in Electronic and Optical Materials

Content: Advances in Electronic Materials for Clean Energy Conversion and Storage Applications reviews green synthesis and fabrication techniques of various electronic materials and their derivatives for applications in photovoltaics. The book investigates recent advances, progress and issues of photovoltaic-based research, including organic, hybrid, dye-sensitized, polymer, and quantum dot-based solar cells. There is a focus on applications for clean energy and storage in the book. Clean energy is defined as energy derived from renewable resources or zero-emission sources and natural processes that are regenerative and sustainable resources such as biomass, geothermal energy, hydropower, solar and wind energy. Materials discussed include nanomaterials, nanocomposites, polymers, and polymer-composites. Advances in clean energy conversion and energy storage devices are also reviewed thoroughly based on recent research and developments such as supercapacitors, batteries etc. Reliable methods to characterize and analyze these materials systems and devices are emphasized throughout the book. Important information on synthesis and analytical chemistry of these important systems are reviewed, but also material science methods to investigate optical properties of carbon-nanomaterials, metal oxide nanomaterials and their nanocomposites.

Note: Part I: Advanced electronic materials for solar energy applications -- 1. Introduction to advanced electronic materials for solar energy applications -- 2. Advanced electronic materials for engineering energy applications -- 3. Carbon-based nanomaterials for solar energy -- 4. Quantum dots/Nanoparticles for solar energy -- 5. Organic semiconducting materials for solar energy -- 6. Small molecule organic solar cells -- 7. Polymer Organic Solar Cells -- 8. Metal halide hybrid perovskite materials for solar energy -- 9. Metal-halide perovskite nanomaterials and applications -- 10. Metal-halide perovskites for hybrid solar cells -- 11. Photon-downconversion materials for solar energy -- 12. Quantum dot as photon-downconversion materials -- 13. Organic dyes as photon-downconversion materials -- 14. Polymer-based nanocomposite for solar energy applications -- 15. Prospects and future perspective of electronic materials for solar cell applications -- Part II. Advanced electronic materials for energy storage (supercapacitor and battery) applications -- 16. Introduction to advanced electronic materials for energy storage applications -- 17. Advanced electronic materials for engineering energy storage applications -- 18. Carbon-based nanomaterials for supercapacitor electrode materials -- 19. Transition metal oxide nanomaterials as electrodes for supercapacitor applications -- 20. Transition metal oxides as electrode materials -- 21. Graphene derivative/transition metal oxides nanocomposites as electrode materials -- 22. Polymers-based nanocomposite as electrode materials for supercapacitor applications -- 23. Transition metal oxide nanomaterials-based electrodes for battery applications -- 24. Carbon-based nanomaterials for battery applications -- 25. Graphene-derivative decorated transition-metal oxide nanocomposites for battery applications -- 26. Prospects and future perspective of nanomaterials for energy storage applications

Additional Edition: Print version: Khan, Aftab Aslam Parwaz Advances in Electronic Materials for Clean Energy Conversion and Storage Applications San Diego : Elsevier Science & Technology,c2023

Language: English

UID:

Format: 1 online resource (569 pages)

ISBN: 0-323-98400-2

Content: Advanced Applications of Ionic Liquids discusses the intersection of nanotechnology with ionic liquids (ILs) and materials, along with opportunities for advanced engineering applications in various research fields. Novel materials at nano scales with ILs creates an upsurge in the thermal and electrochemical constancy of the nano scale particles, making them ideal for industrial applications. The implementation of ILs at nano scale includes an interaction of constituents, which is beneficial for electron transfer reactions. These new composites can be implemented as sensors, electronics, catalysts and photonics. Including ILs in polymer composites enhance electrochemical consistency, govern particle size, upsurge conductivity, reduce toxicity, and more.

Note: Front Cover -- Advanced Applications of Ionic Liquids -- Copyright Page -- Dedication -- Contents -- List of contributors -- About the editors -- Preface -- 1 Catalysis and electrochemistry -- 1 Progressions in ionic liquid-based electrochemical research -- 1.1 Introduction -- 1.2 Physical properties of ionic liquids -- 1.2.1 Conductivity -- 1.2.2 Viscosity -- 1.2.3 Electrochemical potential window -- 1.3 Electrochemical properties -- 1.4 Applications of ionic liquids in electrochemistry -- 1.4.1 Electrochemical sensors -- 1.4.2 Electrodeposition -- 1.4.3 Electroredox -- 1.4.4 Electrochemical biosensors -- 1.4.5 Applications of ionic liquids in Li-ion batteries -- 1.4.6 Applications of ionic liquids for supercapacitors -- 1.4.7 Applications of ionic liquids in electropolymerization -- 1.5 Conclusion -- References -- 2 Recapitulation on the separation and purification of biomolecules using ionic liquid-based aqueous biphasic systems -- 2.1 Introduction -- 2.2 Applications of ionic liquids-based aqueous biphasic system in separation and purification of biomolecules -- 2.2.1 Amino acids -- 2.2.2 Proteins -- 2.2.3 Enzymes -- 2.2.4 Nucleic acids -- 2.3 Conclusion -- Acknowledgments -- Nomenclature -- Abbreviations -- Ionic Liquids and Good Buffers -- Proteins -- Enzymes -- Salts -- Acid -- References -- 3 Current trends and applications of ionic liquids in electrochemical devices -- 3.1 Introduction -- 3.1.1 History of ionic liquids in electrochemical devices -- 3.2 Ionic liquids in energy storage devices and conversion materials -- 3.3 Ionic liquid in energy sustainability and CO2 sequestration -- 3.4 Ionic liquids as a novel electrolyte medium for advanced electrochemical devices -- 3.5 Ionic liquids' electrochemical sensing properties -- 3.6 Applications of room-temperature ionic liquids. , 3.6.1 Electrochemical applications of room-temperature ionic liquids -- 3.6.2 Room-temperature ionic liquid as a nonfaradaic biosensing component -- 3.6.3 Room-temperature ionic liquids in electrochemical gas sensoring -- 3.7 Ammonium, pyrrolidinium, phosphonium, and sulfonium-based ionic liquids and electrochemical properties -- 3.8 Current and future prospects -- 3.8.1 Ionic liquids as electrolytes -- 3.8.2 Ionic liquids as lubricants and hydraulic fluids -- 3.8.3 Ionic liquids as chemical production processes -- 3.8.4 Ionic liquids as hydrogen storage -- 3.9 Conclusions -- References -- 4 Green chemistry of ionic liquids in surface electrochemistry -- 4.1 Introduction -- 4.1.1 Important characteristics of electrochemical reactions -- 4.1.1.1 Electrochemical current and potential -- 4.1.1.2 Electrochemical interfaces -- 4.1.1.3 Models of electrochemical electron transfer -- 4.1.2 Electrochemistry at the molecular scale -- 4.1.2.1 Surface structure -- 4.1.2.2 Bonding of ions -- 4.1.2.3 Bonding of water -- 4.1.2.4 Experimental aspects of current/voltage properties -- 4.1.3 Ionic liquids properties pertinent to surface electrochemistry -- 4.2 Role of ionic liquids in surface electrochemistry -- 4.2.1 Carbon ionic liquid electrode -- 4.2.1.1 Direct electrochemistry of hemoglobin -- 4.2.1.2 Determination of various substances -- 4.2.2 Quartz crystal microbalance -- 4.2.3 Chemical warfare agent -- 4.2.4 Electrochemical oxidation -- 4.3 Conclusions -- References -- 5 An evolution in electrochemical and chemical synthesis applications in prospects of ionic liquids -- 5.1 Introduction -- 5.2 Electrochemical oxidation reactions using room-temperature ionic liquids -- 5.2.1 Oxidative self-coupling reaction -- 5.2.2 Shono oxidation of carbamates -- 5.2.3 Oxidation of alcohols -- 5.2.4 Bromination reaction. , 5.3 Electrochemical reduction reactions using room-temperature ionic liquid -- 5.3.1 Electroreductive coupling of organic halides -- 5.3.2 Pinacol coupling reaction -- 5.3.3 Electrochemical reduction of carbon dioxide gas -- 5.3.4 Electrocarboxylation reaction -- 5.3.5 Synthesis of aryl zinc compounds -- 5.3.6 Electrochemical reductive coupling to form 1,6-diketone -- 5.3.7 Electrochemical reduction of benzoyl chloride -- 5.3.8 Organocatalysis using electrogenerated bases -- 5.4 Electrochemical polymerization reactions using room-temperature ionic liquids -- 5.5 Electrochemical partial fluorination using room-temperature ionic liquids -- 5.5.1 Anodic fluorination of dithioacetals -- 5.5.2 Electrochemical fluorination utilizing mediators -- 5.5.3 Fluorination of methyl adamantane-1-carboxylate electrochemically -- 5.6 Other electrochemical reactions using room-temperature ionic liquids -- 5.6.1 Electrogenerated N-heterocyclic carbenes -- 5.6.1.1 Synthesis of β-lactams -- 5.6.1.2 Henry reaction -- 5.6.1.3 Benzoin condensation -- 5.6.1.4 Stetter reaction -- 5.6.1.5 Staudinger reaction -- 5.6.1.6 Preparation of γ-butyrolactones -- 5.6.1.7 Esterification reaction -- 5.6.1.8 Transesterification -- 5.6.1.9 Oxidative esterification of aromatic aldehydes -- 5.6.1.10 Preparation of N-acyloxazolidin-2-ones -- 5.6.1.11 N-Functionalisation of benzoxazolones -- 5.6.2 Functionalisation of nitroaromatic compounds -- 5.6.3 Epoxidation reaction using room-temperature ionic liquids -- 5.7 Conclusions -- Abbreviations -- References -- 6 Recent changes in the synthesis of ionic liquids based on inorganic nanocomposites and their applications -- 6.1 Introduction -- 6.1.1 Inorganic nanocomposite materials-an overview -- 6.1.2 Development of inorganic nanocomposite materials synthesis -- 6.1.3 Role of ionic liquid in the synthesis of inorganic nanocomposite. , 6.1.4 Application-based importance of ionic liquids in inorganic nanocomposite -- 6.2 Synthesis of inorganic nanocomposite materials using ionic liquid -- 6.2.1 Sol-gel method -- 6.2.2 Hydrothermal method -- 6.2.3 Microemulsion method -- 6.2.4 Precipitation and co-precipitation method -- 6.2.5 Rays mediated method -- 6.2.5.1 Photochemical method -- 6.2.5.2 Photocatalytic deposition -- 6.2.5.3 Sonochemical method -- 6.2.6 Electrochemical method -- 6.3 How organic-inorganic is different from inorganic nanocomposites? -- 6.4 Recent advancements and advantages of inorganic nanocomposites with ionic liquids -- 6.4.1 Storage of heat energy -- 6.4.1.1 Advantages -- 6.4.2 Electrolytic support -- 6.4.2.1 Advantages -- 6.4.3 Solvents improvement -- 6.4.3.1 Advantages -- 6.4.4 Analytics and purity -- 6.4.4.1 Advantages -- 6.4.5 Additives -- 6.4.5.1 Advantages -- 6.5 Current applications and their future perspective -- 6.5.1 Biomedical -- 6.5.2 Environmental science -- 6.5.2.1 Water treatment -- 6.5.2.2 Soil treatment -- 6.5.2.3 Air pollution treatment -- 6.5.3 Nuclear science -- 6.5.4 Food science -- 6.5.5 Energy storage and transfer -- 6.5.6 Catalysis -- 6.5.7 Lubricants -- 6.5.8 Sensors -- 6.5.9 Electrochemistry -- 6.6 Reaction mechanism of ionic liquids-based synthesized nanocomposite materials -- 6.7 Conclusions -- Abbreviations -- Author contributions -- Conflicts of interest -- References -- 7 Ionic liquids as green and efficient corrosion-protective materials for metals and alloys -- 7.1 Introduction -- 7.1.1 Effect of corrosion -- 7.1.2 Causes of corrosion -- 7.1.3 Techniques of corrosion protection -- 7.1.4 Ionic liquids as green corrosion protectors -- 7.1.5 Applications of ionic liquids -- 7.1.6 Classification of ionic liquids -- 7.2 Ionic liquids as corrosion protector for metals and alloy. , 7.2.1 Ionic liquids as corrosion protector for iron and alloy -- 7.2.2 Ionic liquids as corrosion protector for Al -- 7.2.3 Ionic liquids as corrosion protector for Cu and Zn -- 7.3 Corrosion protection mechanism -- 7.4 Conclusions and future perspectives -- References -- 2 Separation technology -- 8 Ionic liquids as valuable assets in extraction techniques -- 8.1 Introduction -- 8.2 Ionic liquids -- 8.3 Ionic liquids for the extraction of natural products from the plants -- 8.3.1 Ultrasonic-assisted ionic liquid approach for the extraction of natural products -- 8.3.2 Microwave-assisted ionic liquid approach for the extraction of natural products -- 8.3.3 Reactive dissolution of biomass in ionic liquids for the extraction of natural products -- 8.4 Ionic liquids in extraction of pharmaceuticals from biological and environmental samples -- 8.5 Ionic liquids for the extraction of contaminants from wastewater -- 8.5.1 Extraction of toxic metal ions -- 8.5.2 Extraction of organic pollutants -- 8.6 Ionic liquids for the extraction of soil contaminants and soil organic matter -- 8.6.1 Extraction of soil contaminants -- 8.6.1.1 Extraction of soil organic pollutants -- 8.6.1.2 Extraction of soil heavy metal ions -- 8.6.2 Extractions of soil organic matter -- 8.7 Extraction of rare earth metals -- 8.8 Ionic liquids for the extraction of food contaminants -- 8.9 Applications of ionic liquids -- 8.10 Conclusion and future prospective -- Acknowledgments -- References -- 9 An involvement of ionic liquids and other small molecules as promising corrosion inhibitors in recent advancement of tech... -- 9.1 Consequences of corrosion -- 9.2 Economic effects -- 9.3 Methods to control corrosion -- 9.3.1 Material selection -- 9.3.2 Coating -- 9.3.2.1 Metallic coating -- 9.3.2.2 Organic coating -- 9.3.2.3 Inorganic coatings -- 9.4 Inhibitors -- 9.5 Anodization -- 9.6 Cathodic protection.

Additional Edition: Print version: Siddique, Jamal Akhter Advanced Applications of Ionic Liquids San Diego : Elsevier,c2022 ISBN 9780323999212

Language: English

UID:

Format: 1 online resource (569 pages)

ISBN: 0-323-98400-2

Content: Advanced Applications of Ionic Liquids discusses the intersection of nanotechnology with ionic liquids (ILs) and materials, along with opportunities for advanced engineering applications in various research fields. Novel materials at nano scales with ILs creates an upsurge in the thermal and electrochemical constancy of the nano scale particles, making them ideal for industrial applications. The implementation of ILs at nano scale includes an interaction of constituents, which is beneficial for electron transfer reactions. These new composites can be implemented as sensors, electronics, catalysts and photonics. Including ILs in polymer composites enhance electrochemical consistency, govern particle size, upsurge conductivity, reduce toxicity, and more.

Note: Front Cover -- Advanced Applications of Ionic Liquids -- Copyright Page -- Dedication -- Contents -- List of contributors -- About the editors -- Preface -- 1 Catalysis and electrochemistry -- 1 Progressions in ionic liquid-based electrochemical research -- 1.1 Introduction -- 1.2 Physical properties of ionic liquids -- 1.2.1 Conductivity -- 1.2.2 Viscosity -- 1.2.3 Electrochemical potential window -- 1.3 Electrochemical properties -- 1.4 Applications of ionic liquids in electrochemistry -- 1.4.1 Electrochemical sensors -- 1.4.2 Electrodeposition -- 1.4.3 Electroredox -- 1.4.4 Electrochemical biosensors -- 1.4.5 Applications of ionic liquids in Li-ion batteries -- 1.4.6 Applications of ionic liquids for supercapacitors -- 1.4.7 Applications of ionic liquids in electropolymerization -- 1.5 Conclusion -- References -- 2 Recapitulation on the separation and purification of biomolecules using ionic liquid-based aqueous biphasic systems -- 2.1 Introduction -- 2.2 Applications of ionic liquids-based aqueous biphasic system in separation and purification of biomolecules -- 2.2.1 Amino acids -- 2.2.2 Proteins -- 2.2.3 Enzymes -- 2.2.4 Nucleic acids -- 2.3 Conclusion -- Acknowledgments -- Nomenclature -- Abbreviations -- Ionic Liquids and Good Buffers -- Proteins -- Enzymes -- Salts -- Acid -- References -- 3 Current trends and applications of ionic liquids in electrochemical devices -- 3.1 Introduction -- 3.1.1 History of ionic liquids in electrochemical devices -- 3.2 Ionic liquids in energy storage devices and conversion materials -- 3.3 Ionic liquid in energy sustainability and CO2 sequestration -- 3.4 Ionic liquids as a novel electrolyte medium for advanced electrochemical devices -- 3.5 Ionic liquids' electrochemical sensing properties -- 3.6 Applications of room-temperature ionic liquids. , 3.6.1 Electrochemical applications of room-temperature ionic liquids -- 3.6.2 Room-temperature ionic liquid as a nonfaradaic biosensing component -- 3.6.3 Room-temperature ionic liquids in electrochemical gas sensoring -- 3.7 Ammonium, pyrrolidinium, phosphonium, and sulfonium-based ionic liquids and electrochemical properties -- 3.8 Current and future prospects -- 3.8.1 Ionic liquids as electrolytes -- 3.8.2 Ionic liquids as lubricants and hydraulic fluids -- 3.8.3 Ionic liquids as chemical production processes -- 3.8.4 Ionic liquids as hydrogen storage -- 3.9 Conclusions -- References -- 4 Green chemistry of ionic liquids in surface electrochemistry -- 4.1 Introduction -- 4.1.1 Important characteristics of electrochemical reactions -- 4.1.1.1 Electrochemical current and potential -- 4.1.1.2 Electrochemical interfaces -- 4.1.1.3 Models of electrochemical electron transfer -- 4.1.2 Electrochemistry at the molecular scale -- 4.1.2.1 Surface structure -- 4.1.2.2 Bonding of ions -- 4.1.2.3 Bonding of water -- 4.1.2.4 Experimental aspects of current/voltage properties -- 4.1.3 Ionic liquids properties pertinent to surface electrochemistry -- 4.2 Role of ionic liquids in surface electrochemistry -- 4.2.1 Carbon ionic liquid electrode -- 4.2.1.1 Direct electrochemistry of hemoglobin -- 4.2.1.2 Determination of various substances -- 4.2.2 Quartz crystal microbalance -- 4.2.3 Chemical warfare agent -- 4.2.4 Electrochemical oxidation -- 4.3 Conclusions -- References -- 5 An evolution in electrochemical and chemical synthesis applications in prospects of ionic liquids -- 5.1 Introduction -- 5.2 Electrochemical oxidation reactions using room-temperature ionic liquids -- 5.2.1 Oxidative self-coupling reaction -- 5.2.2 Shono oxidation of carbamates -- 5.2.3 Oxidation of alcohols -- 5.2.4 Bromination reaction. , 5.3 Electrochemical reduction reactions using room-temperature ionic liquid -- 5.3.1 Electroreductive coupling of organic halides -- 5.3.2 Pinacol coupling reaction -- 5.3.3 Electrochemical reduction of carbon dioxide gas -- 5.3.4 Electrocarboxylation reaction -- 5.3.5 Synthesis of aryl zinc compounds -- 5.3.6 Electrochemical reductive coupling to form 1,6-diketone -- 5.3.7 Electrochemical reduction of benzoyl chloride -- 5.3.8 Organocatalysis using electrogenerated bases -- 5.4 Electrochemical polymerization reactions using room-temperature ionic liquids -- 5.5 Electrochemical partial fluorination using room-temperature ionic liquids -- 5.5.1 Anodic fluorination of dithioacetals -- 5.5.2 Electrochemical fluorination utilizing mediators -- 5.5.3 Fluorination of methyl adamantane-1-carboxylate electrochemically -- 5.6 Other electrochemical reactions using room-temperature ionic liquids -- 5.6.1 Electrogenerated N-heterocyclic carbenes -- 5.6.1.1 Synthesis of β-lactams -- 5.6.1.2 Henry reaction -- 5.6.1.3 Benzoin condensation -- 5.6.1.4 Stetter reaction -- 5.6.1.5 Staudinger reaction -- 5.6.1.6 Preparation of γ-butyrolactones -- 5.6.1.7 Esterification reaction -- 5.6.1.8 Transesterification -- 5.6.1.9 Oxidative esterification of aromatic aldehydes -- 5.6.1.10 Preparation of N-acyloxazolidin-2-ones -- 5.6.1.11 N-Functionalisation of benzoxazolones -- 5.6.2 Functionalisation of nitroaromatic compounds -- 5.6.3 Epoxidation reaction using room-temperature ionic liquids -- 5.7 Conclusions -- Abbreviations -- References -- 6 Recent changes in the synthesis of ionic liquids based on inorganic nanocomposites and their applications -- 6.1 Introduction -- 6.1.1 Inorganic nanocomposite materials-an overview -- 6.1.2 Development of inorganic nanocomposite materials synthesis -- 6.1.3 Role of ionic liquid in the synthesis of inorganic nanocomposite. , 6.1.4 Application-based importance of ionic liquids in inorganic nanocomposite -- 6.2 Synthesis of inorganic nanocomposite materials using ionic liquid -- 6.2.1 Sol-gel method -- 6.2.2 Hydrothermal method -- 6.2.3 Microemulsion method -- 6.2.4 Precipitation and co-precipitation method -- 6.2.5 Rays mediated method -- 6.2.5.1 Photochemical method -- 6.2.5.2 Photocatalytic deposition -- 6.2.5.3 Sonochemical method -- 6.2.6 Electrochemical method -- 6.3 How organic-inorganic is different from inorganic nanocomposites? -- 6.4 Recent advancements and advantages of inorganic nanocomposites with ionic liquids -- 6.4.1 Storage of heat energy -- 6.4.1.1 Advantages -- 6.4.2 Electrolytic support -- 6.4.2.1 Advantages -- 6.4.3 Solvents improvement -- 6.4.3.1 Advantages -- 6.4.4 Analytics and purity -- 6.4.4.1 Advantages -- 6.4.5 Additives -- 6.4.5.1 Advantages -- 6.5 Current applications and their future perspective -- 6.5.1 Biomedical -- 6.5.2 Environmental science -- 6.5.2.1 Water treatment -- 6.5.2.2 Soil treatment -- 6.5.2.3 Air pollution treatment -- 6.5.3 Nuclear science -- 6.5.4 Food science -- 6.5.5 Energy storage and transfer -- 6.5.6 Catalysis -- 6.5.7 Lubricants -- 6.5.8 Sensors -- 6.5.9 Electrochemistry -- 6.6 Reaction mechanism of ionic liquids-based synthesized nanocomposite materials -- 6.7 Conclusions -- Abbreviations -- Author contributions -- Conflicts of interest -- References -- 7 Ionic liquids as green and efficient corrosion-protective materials for metals and alloys -- 7.1 Introduction -- 7.1.1 Effect of corrosion -- 7.1.2 Causes of corrosion -- 7.1.3 Techniques of corrosion protection -- 7.1.4 Ionic liquids as green corrosion protectors -- 7.1.5 Applications of ionic liquids -- 7.1.6 Classification of ionic liquids -- 7.2 Ionic liquids as corrosion protector for metals and alloy. , 7.2.1 Ionic liquids as corrosion protector for iron and alloy -- 7.2.2 Ionic liquids as corrosion protector for Al -- 7.2.3 Ionic liquids as corrosion protector for Cu and Zn -- 7.3 Corrosion protection mechanism -- 7.4 Conclusions and future perspectives -- References -- 2 Separation technology -- 8 Ionic liquids as valuable assets in extraction techniques -- 8.1 Introduction -- 8.2 Ionic liquids -- 8.3 Ionic liquids for the extraction of natural products from the plants -- 8.3.1 Ultrasonic-assisted ionic liquid approach for the extraction of natural products -- 8.3.2 Microwave-assisted ionic liquid approach for the extraction of natural products -- 8.3.3 Reactive dissolution of biomass in ionic liquids for the extraction of natural products -- 8.4 Ionic liquids in extraction of pharmaceuticals from biological and environmental samples -- 8.5 Ionic liquids for the extraction of contaminants from wastewater -- 8.5.1 Extraction of toxic metal ions -- 8.5.2 Extraction of organic pollutants -- 8.6 Ionic liquids for the extraction of soil contaminants and soil organic matter -- 8.6.1 Extraction of soil contaminants -- 8.6.1.1 Extraction of soil organic pollutants -- 8.6.1.2 Extraction of soil heavy metal ions -- 8.6.2 Extractions of soil organic matter -- 8.7 Extraction of rare earth metals -- 8.8 Ionic liquids for the extraction of food contaminants -- 8.9 Applications of ionic liquids -- 8.10 Conclusion and future prospective -- Acknowledgments -- References -- 9 An involvement of ionic liquids and other small molecules as promising corrosion inhibitors in recent advancement of tech... -- 9.1 Consequences of corrosion -- 9.2 Economic effects -- 9.3 Methods to control corrosion -- 9.3.1 Material selection -- 9.3.2 Coating -- 9.3.2.1 Metallic coating -- 9.3.2.2 Organic coating -- 9.3.2.3 Inorganic coatings -- 9.4 Inhibitors -- 9.5 Anodization -- 9.6 Cathodic protection.

Additional Edition: Print version: Siddique, Jamal Akhter Advanced Applications of Ionic Liquids San Diego : Elsevier,c2022 ISBN 9780323999212

Language: English

UID:

Format: 1 online resource (604 pages)

ISBN: 9780323912068

Content: Advances in Electronic Materials for Clean Energy Conversion and Storage Applications reviews green synthesis and fabrication techniques of various electronic materials and their derivatives for applications in photovoltaics. The book investigates recent advances, progress and issues of photovoltaic-based research, including organic, hybrid, dye-sensitized, polymer, and quantum dot-based solar cells. There is a focus on applications for clean energy and storage in the book. Clean energy is defined as energy derived from renewable resources or zero-emission sources and natural processes that are regenerative and sustainable resources such as biomass, geothermal energy, hydropower, solar and wind energy. Materials discussed include nanomaterials, nanocomposites, polymers, and polymer-composites. Advances in clean energy conversion and energy storage devices are also reviewed thoroughly based on recent research and developments such as supercapacitors, batteries etc. Reliable methods to characterize and analyze these materials systems and devices are emphasized throughout the book. Important information on synthesis and analytical chemistry of these important systems are reviewed, but also material science methods to investigate optical properties of carbon-nanomaterials, metal oxide nanomaterials and their nanocomposites. Reviews the latest advances in electronic materials synthesis, fabrication and application in energy Discusses green, cost-effective, simple and large-scale production of electronic materials Includes critical materials and device characterization techniques that enhance our understanding of materials' properties and measure device performance.

Note: Part I: Advanced electronic materials for solar energy applications -- 1. Introduction to advanced electronic materials for solar energy applications -- 2. Advanced electronic materials for engineering energy applications -- 3. Carbon-based nanomaterials for solar energy -- 4. Quantum dots/Nanoparticles for solar energy -- 5. Organic semiconducting materials for solar energy -- 6. Small molecule organic solar cells -- 7. Polymer Organic Solar Cells -- 8. Metal halide hybrid perovskite materials for solar energy -- 9. Metal-halide perovskite nanomaterials and applications -- 10. Metal-halide perovskites for hybrid solar cells -- 11. Photon-downconversion materials for solar energy -- 12. Quantum dot as photon-downconversion materials -- 13. Organic dyes as photon-downconversion materials -- 14. Polymer-based nanocomposite for solar energy applications -- 15. Prospects and future perspective of electronic materials for solar cell applications -- Part II. Advanced electronic materials for energy storage (supercapacitor and battery) applications -- 16. Introduction to advanced electronic materials for energy storage applications -- 17. Advanced electronic materials for engineering energy storage applications -- 18. Carbon-based nanomaterials for supercapacitor electrode materials -- 19. Transition metal oxide nanomaterials as electrodes for supercapacitor applications -- 20. Transition metal oxides as electrode materials -- 21. Graphene derivative/transition metal oxides nanocomposites as electrode materials -- 22. Polymers-based nanocomposite as electrode materials for supercapacitor applications -- 23. Transition metal oxide nanomaterials-based electrodes for battery applications -- 24. Carbon-based nanomaterials for battery applications -- 25. Graphene-derivative decorated transition-metal oxide nanocomposites for battery applications -- 26. Prospects and future perspective of nanomaterials for energy storage applications.

Language: English