Molecular Self Assembly: Emerging Frontiers in DNA Nanotechnology and Biomimetic Design

Chapters Brief Overview:

1: Molecular selfassembly – Examines the fundamental principles driving autonomous molecular organization.

2: Molecular engineering – Explores techniques for designing molecules with precise structural properties.

3: Resorcinarene – Introduces macrocyclic molecules used for templated nanostructures.

4: Supramolecular catalysis – Highlights catalytic processes enabled by noncovalent molecular interactions.

5: Selfassembly of nanoparticles – Discusses strategies for arranging nanoparticles into functional assemblies.

6: Bacillus virus phi29 – Analyzes the selfassembling properties of this bacteriophage in nanotechnology.

7: DNA origami – Details the folding of DNA into nanoscale structures with programmable functionality.

8: Molecular machine – Explores nanoscale devices that perform mechanical work at the molecular level.

9: Supramolecular polymer – Introduces polymeric materials formed through reversible molecular interactions.

10: Protein complex – Examines naturally occurring selfassembling protein structures and their applications.

11: DNA nanotechnology – Provides a deep dive into DNAbased molecular construction techniques.

12: Selfassembly – Covers broad concepts of spontaneous molecular organization across various disciplines.

13: Mechanically interlocked molecular architectures – Discusses the unique properties of topologically linked molecules.

14: Nanotechnology – Explores the broader applications of nanoscale engineering beyond DNAbased systems.

15: Supramolecular chemistry – Introduces the chemistry of noncovalent interactions governing molecular assembly.

16: Roeland Nolte – Highlights contributions of this pioneer in supramolecular chemistry and nanotechnology.

17: Nanobiotechnology – Examines the intersection of nanotechnology and biology for medical advancements.

18: RNA origami – Describes RNAbased selfassembly techniques for creating programmable nanostructures.

19: Crystal engineering – Explores the design of crystalline materials using selfassembly principles.

20: Macromolecular cages – Introduces hollow molecular structures with potential in drug delivery and catalysis.

21: Molecular recognition – Investigates how molecules selectively interact to form complex assemblies.

By mastering molecular selfassembly, readers will gain insights into how nature builds intricate nanostructures and how these principles can be harnessed for revolutionary applications. Whether you are a student, researcher, or hobbyist, this book provides a solid foundation in one of the most exciting frontiers of science.