Amsterdam, Netherlands : , : Woodhead Publishing, , 2015

©2015

0-08-100261-0

0-08-100250-5

1 online resource (328 p.)

Woodhead Publishing series in electronic and optical materials ; ; Number 83

547.84

Block copolymers

Self-assembly (Chemistry)

Nanomanufacturing

Inglese

Description based upon print version of record.

Includes bibliographical references at the end of each chapters and index.

Front Cover; Directed Self-assembly of Block Copolymers for Nano-manufacturing; Copyright; Contents; List of contributors; Woodhead Publishing Series in Electronic and Optical Materials; Part One: Physics and chemistry of block copolymer (BCP) materials ; Chapter 1: Physics of block copolymers from bulk to thin films; 1.1 . Introduction; 1.2 . Order-disorder transition of block copolymers; 1.2.1 . Disordered state; 1.2.2 . Weak segregation limit in ordered state; 1.2.3 . Strong segregation limit in ordered state; 1.2.4 . Phase diagram obtained by using self-consistent field theory

1.3 . Morphologies of diblock copolymer/homopolymer mixtures1.4 . Dynamics of phase transition in block copolymers; 1.5 . Structures of block copolymer in thin films; 1.5.1 . Free energy of block copolymer thin film; 1.5.2 . Effect of surface energy term;  F surface ; 1.5.3 . Effect of bulk energy term F bulk ; 1.6 . Conclusion; References; Chapter 2: RAFT synthesis of block copolymers and their self-assembly properties; 2.1 . RAFT process description; 2.2 . Polymerization process details; 2.2.1 . In situ process analysis; 2.3 . RAFT end-group catalytic radical reduction

2.4 . Block Copolymer In situ Topcoat Applications2.5 . DSA Applications; 2.6 . High chi block copolymers; 2.7 . Conclusions; Acknowledgments; References; Chapter 3: Thermal and solvent annealing of block copolymer films; 3.1 . Introduction; 3.2 . Thermal annealing of BCPs films; 3.2.1 . Fundamental consideration; 3.2.2 . Film thickness effect and temperature gradient; 3.2.3 . Crystallization behavior induced by thermal annealing; 3.3 . Solvent annealing of BCPs films; 3.3.1 . Fundamental consideration; 3.3.2 . Factors affecting the annealing process

3.3.3 . Combination of solvent annealing and thermal annealing3.4 . Summary and outlook; References; Chapter 4: Field-theoretic simulations and self-consistent field theory for studying block copolymer directed self-assembly; 4.1  Introduction; 4.2  Overview of field-theory-based simulations of block copolymer DSA; 4.3  Chemoepitaxy modeling; 4.4  Graphoepitaxy modeling; 4.4.1  Cylinders in a rectangular trench; 4.4.2  Contact hole shrink; 4.5  Summary and outlook; References; Part Two: Templates and patterning for directed self-assembly

Chapter 5: Directed self-oriented self-assembly of block copolymers using topographical surfaces5.1 . Introduction; 5.2 . Control of interfacial interactions; 5.3 . Graphoepitaxy; 5.3.1 . Fabrication of topographical surfaces; 5.3.2 . Geometry with deep patterning; 5.3.2.1 . Deep trench surfaces; 5.3.2.2 . Post surfaces; 5.3.2.3 . Other surfaces; 5.3.3 . Geometry with minimal patterning; 5.3.3.1 . Faceted surfaces; 5.3.3.2 . Shallow trench surfaces; 5.4 . Application of BCPs guided by topographical surfaces; 5.5 . Summary and outlook; References

Chapter 6: Directed self-oriented self-assembly of block copolymers using chemically modified surfaces

The directed self-assembly (DSA) method of patterning for microelectronics uses polymer phase-separation to generate features of less than 20nm, with the positions of self-assembling materials externally guided into the desired pattern. Directed self-assembly of Block Co-polymers for Nano-manufacturing reviews the design, production, applications and future developments needed to facilitate the widescale adoption of this promising technology.   Beginning with a solid overview of the physics and chemistry of block copolymer (BCP) materials, Part 1 covers the synthesis of new materials and new