Jonathan L Sessler (USA University of Texas at Austin), Philip Gale (Australia The University of Sydney), Won-Seob Cho
Anion Receptor Chemistry
Herausgeber: Rowan, Stuart J; Rowan, Alan E; Aida, Takuzo
Jonathan L Sessler (USA University of Texas at Austin), Philip Gale (Australia The University of Sydney), Won-Seob Cho
Anion Receptor Chemistry
Herausgeber: Rowan, Stuart J; Rowan, Alan E; Aida, Takuzo
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This book traces the origins of anion recognition as a unique sub-field in supramolecular chemistry, while illustrating the basic approaches used to effect receptor design.
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This book traces the origins of anion recognition as a unique sub-field in supramolecular chemistry, while illustrating the basic approaches used to effect receptor design.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Monographs in Supramolecular Chemistry
- Verlag: Royal Society of Chemistry
- Artikelnr. des Verlages: 11743576
- Seitenzahl: 430
- Erscheinungstermin: 7. April 2006
- Englisch
- Abmessung: 234mm x 155mm x 28mm
- Gewicht: 808g
- ISBN-13: 9780854049745
- ISBN-10: 0854049746
- Artikelnr.: 25888122
- Monographs in Supramolecular Chemistry
- Verlag: Royal Society of Chemistry
- Artikelnr. des Verlages: 11743576
- Seitenzahl: 430
- Erscheinungstermin: 7. April 2006
- Englisch
- Abmessung: 234mm x 155mm x 28mm
- Gewicht: 808g
- ISBN-13: 9780854049745
- ISBN-10: 0854049746
- Artikelnr.: 25888122
Jonathan L Sessler, University of Texas, Austin, TX, USA / Philip A Gale, University of Southampton, UK / Won-Seob Cho, University of Texas, Austin, TX, USA
PREFACE
CHAPTER 1
1.1: Importance of Anions in the Modern World
1.2: The Challenges of Anion Complexation
1.3: Anions in Biological Systems
1.4: Historical Overview of Synthetic Anion Receptor Chemistry
1.5: Measurement Methods: Caveats and Limitations
1.6: Summary Remarks
CHAPTER 2: Classic Charged Non-Metallic Systems
2.1: Polyammoniums
2.2: Quaternary Ammoniums
2.3: Guanidiniums
2.4: Amidiniums
2.5: Imidazoliums
2.6: Thiouronium
2.7: Summary Remarks
CHAPTER 3: Protonated Expanded Porphyrins and Linear Analogues
3.1: Introduction
3.2: Cyclic Systems
3.3: Linear Receptors
3.4: Summary Remarks
CHAPTER 4: Neutral Non-Metallic Systems
4.1: Amide-Based Anion Receptors
4.2: Peptide-Based Receptors
4.3: Urea-Based Anion Receptors
4.4: Alcohol-Based Anion Receptors
4.5: Hybrid Receptors
4.6: Other Systems
4.7: Summary Remarks
CHAPTER 5: Neutral Pyrrole Systems
5.1: Introduction
5.2: Cyclic Receptors
5.3: Linear Receptors
5.4: Summary Remarks
CHAPTER 6: Receptors for Ion Pairs
6.1: Introduction
6.2: Ditopic Receptors
6.3: Cascade Complexes
6.4: Receptors for Zwitterions
6.5: Dual Host Extraction of Salts
6.6: Summary Remarks
CHAPTER 7: Metal and Lewis Acid Based Receptors
7.1: Lewis Acidic Receptors
7.2: Metals as Organizers
7.3: Other Anion Receptors Containing Metals
7.4: Summary Remarks
CHAPTER 8: Sensors
8.1: Introduction
8.2: Devices that Employ Anion Selective Membranes
8.3: Discrete Molecular Electrochemical Anion Sensors
8.4: Discrete Molecular Optical Anion Sensors
8.5: Displacement Assays
8.6: Assays Based on Deaggregation Phenomena
8.7: Summary Remarks
CHAPTER 9: Anion Controlled Assembly and Template-based Synthesis
9.1: Introduction
9.2: Halide Controlled Assemblies
9.3: Oxyanion Directed Assemblies
9.4: Polyfluoro-anion Directed Assemblies
9.5: Summary Remarks
CHAPTER 10: Afterword
CHAPTER 1
1.1: Importance of Anions in the Modern World
1.2: The Challenges of Anion Complexation
1.3: Anions in Biological Systems
1.4: Historical Overview of Synthetic Anion Receptor Chemistry
1.5: Measurement Methods: Caveats and Limitations
1.6: Summary Remarks
CHAPTER 2: Classic Charged Non-Metallic Systems
2.1: Polyammoniums
2.2: Quaternary Ammoniums
2.3: Guanidiniums
2.4: Amidiniums
2.5: Imidazoliums
2.6: Thiouronium
2.7: Summary Remarks
CHAPTER 3: Protonated Expanded Porphyrins and Linear Analogues
3.1: Introduction
3.2: Cyclic Systems
3.3: Linear Receptors
3.4: Summary Remarks
CHAPTER 4: Neutral Non-Metallic Systems
4.1: Amide-Based Anion Receptors
4.2: Peptide-Based Receptors
4.3: Urea-Based Anion Receptors
4.4: Alcohol-Based Anion Receptors
4.5: Hybrid Receptors
4.6: Other Systems
4.7: Summary Remarks
CHAPTER 5: Neutral Pyrrole Systems
5.1: Introduction
5.2: Cyclic Receptors
5.3: Linear Receptors
5.4: Summary Remarks
CHAPTER 6: Receptors for Ion Pairs
6.1: Introduction
6.2: Ditopic Receptors
6.3: Cascade Complexes
6.4: Receptors for Zwitterions
6.5: Dual Host Extraction of Salts
6.6: Summary Remarks
CHAPTER 7: Metal and Lewis Acid Based Receptors
7.1: Lewis Acidic Receptors
7.2: Metals as Organizers
7.3: Other Anion Receptors Containing Metals
7.4: Summary Remarks
CHAPTER 8: Sensors
8.1: Introduction
8.2: Devices that Employ Anion Selective Membranes
8.3: Discrete Molecular Electrochemical Anion Sensors
8.4: Discrete Molecular Optical Anion Sensors
8.5: Displacement Assays
8.6: Assays Based on Deaggregation Phenomena
8.7: Summary Remarks
CHAPTER 9: Anion Controlled Assembly and Template-based Synthesis
9.1: Introduction
9.2: Halide Controlled Assemblies
9.3: Oxyanion Directed Assemblies
9.4: Polyfluoro-anion Directed Assemblies
9.5: Summary Remarks
CHAPTER 10: Afterword
PREFACE
CHAPTER 1
1.1: Importance of Anions in the Modern World
1.2: The Challenges of Anion Complexation
1.3: Anions in Biological Systems
1.4: Historical Overview of Synthetic Anion Receptor Chemistry
1.5: Measurement Methods: Caveats and Limitations
1.6: Summary Remarks
CHAPTER 2: Classic Charged Non-Metallic Systems
2.1: Polyammoniums
2.2: Quaternary Ammoniums
2.3: Guanidiniums
2.4: Amidiniums
2.5: Imidazoliums
2.6: Thiouronium
2.7: Summary Remarks
CHAPTER 3: Protonated Expanded Porphyrins and Linear Analogues
3.1: Introduction
3.2: Cyclic Systems
3.3: Linear Receptors
3.4: Summary Remarks
CHAPTER 4: Neutral Non-Metallic Systems
4.1: Amide-Based Anion Receptors
4.2: Peptide-Based Receptors
4.3: Urea-Based Anion Receptors
4.4: Alcohol-Based Anion Receptors
4.5: Hybrid Receptors
4.6: Other Systems
4.7: Summary Remarks
CHAPTER 5: Neutral Pyrrole Systems
5.1: Introduction
5.2: Cyclic Receptors
5.3: Linear Receptors
5.4: Summary Remarks
CHAPTER 6: Receptors for Ion Pairs
6.1: Introduction
6.2: Ditopic Receptors
6.3: Cascade Complexes
6.4: Receptors for Zwitterions
6.5: Dual Host Extraction of Salts
6.6: Summary Remarks
CHAPTER 7: Metal and Lewis Acid Based Receptors
7.1: Lewis Acidic Receptors
7.2: Metals as Organizers
7.3: Other Anion Receptors Containing Metals
7.4: Summary Remarks
CHAPTER 8: Sensors
8.1: Introduction
8.2: Devices that Employ Anion Selective Membranes
8.3: Discrete Molecular Electrochemical Anion Sensors
8.4: Discrete Molecular Optical Anion Sensors
8.5: Displacement Assays
8.6: Assays Based on Deaggregation Phenomena
8.7: Summary Remarks
CHAPTER 9: Anion Controlled Assembly and Template-based Synthesis
9.1: Introduction
9.2: Halide Controlled Assemblies
9.3: Oxyanion Directed Assemblies
9.4: Polyfluoro-anion Directed Assemblies
9.5: Summary Remarks
CHAPTER 10: Afterword
CHAPTER 1
1.1: Importance of Anions in the Modern World
1.2: The Challenges of Anion Complexation
1.3: Anions in Biological Systems
1.4: Historical Overview of Synthetic Anion Receptor Chemistry
1.5: Measurement Methods: Caveats and Limitations
1.6: Summary Remarks
CHAPTER 2: Classic Charged Non-Metallic Systems
2.1: Polyammoniums
2.2: Quaternary Ammoniums
2.3: Guanidiniums
2.4: Amidiniums
2.5: Imidazoliums
2.6: Thiouronium
2.7: Summary Remarks
CHAPTER 3: Protonated Expanded Porphyrins and Linear Analogues
3.1: Introduction
3.2: Cyclic Systems
3.3: Linear Receptors
3.4: Summary Remarks
CHAPTER 4: Neutral Non-Metallic Systems
4.1: Amide-Based Anion Receptors
4.2: Peptide-Based Receptors
4.3: Urea-Based Anion Receptors
4.4: Alcohol-Based Anion Receptors
4.5: Hybrid Receptors
4.6: Other Systems
4.7: Summary Remarks
CHAPTER 5: Neutral Pyrrole Systems
5.1: Introduction
5.2: Cyclic Receptors
5.3: Linear Receptors
5.4: Summary Remarks
CHAPTER 6: Receptors for Ion Pairs
6.1: Introduction
6.2: Ditopic Receptors
6.3: Cascade Complexes
6.4: Receptors for Zwitterions
6.5: Dual Host Extraction of Salts
6.6: Summary Remarks
CHAPTER 7: Metal and Lewis Acid Based Receptors
7.1: Lewis Acidic Receptors
7.2: Metals as Organizers
7.3: Other Anion Receptors Containing Metals
7.4: Summary Remarks
CHAPTER 8: Sensors
8.1: Introduction
8.2: Devices that Employ Anion Selective Membranes
8.3: Discrete Molecular Electrochemical Anion Sensors
8.4: Discrete Molecular Optical Anion Sensors
8.5: Displacement Assays
8.6: Assays Based on Deaggregation Phenomena
8.7: Summary Remarks
CHAPTER 9: Anion Controlled Assembly and Template-based Synthesis
9.1: Introduction
9.2: Halide Controlled Assemblies
9.3: Oxyanion Directed Assemblies
9.4: Polyfluoro-anion Directed Assemblies
9.5: Summary Remarks
CHAPTER 10: Afterword