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Literature DB >> 29382766

Relevance of packing to colloidal self-assembly.

Rose K Cersonsky¹, Greg van Anders^2,3, Paul M Dodd², Sharon C Glotzer^4,2,3,5,6.

Abstract

Since the 1920s, packing arguments have been used to rationalize crystal structures in systems ranging from atomic mixtures to colloidal crystals. Packing arguments have recently been applied to complex nanoparticle structures, where they often, but not always, work. We examine when, if ever, packing is a causal mechanism in hard particle approximations of colloidal crystals. We investigate three crystal structures composed of their ideal packing shapes. We show that, contrary to expectations, the ordering mechanism cannot be packing, even when the thermodynamically self-assembled structure is the same as that of the densest packing. We also show that the best particle shapes for hard particle colloidal crystals at any finite pressure are imperfect versions of the ideal packing shape.

Keywords: assembly; colloids; digital alchemy; packing; shape entropy

Year: 2018 PMID： 29382766 PMCID： PMC5816204 DOI： 10.1073/pnas.1720139115

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

32 in total

1. Dense regular packings of irregular nonconvex particles.

Authors: Joost de Graaf; René van Roij; Marjolein Dijkstra
Journal: Phys Rev Lett Date: 2011-10-03 Impact factor: 9.161

2. Why is random close packing reproducible?

Authors: Randall D Kamien; Andrea J Liu
Journal: Phys Rev Lett Date: 2007-10-09 Impact factor: 9.161

3. Phase diagram and structural diversity of a family of truncated cubes: degenerate close-packed structures and vacancy-rich states.

Authors: Anjan P Gantapara; Joost de Graaf; René van Roij; Marjolein Dijkstra
Journal: Phys Rev Lett Date: 2013-07-01 Impact factor: 9.161

4. Shape-controlled synthesis of gold and silver nanoparticles.

Authors: Yugang Sun; Younan Xia
Journal: Science Date: 2002-12-13 Impact factor: 47.728

5. Mesophase behaviour of polyhedral particles.

Authors: Umang Agarwal; Fernando A Escobedo
Journal: Nat Mater Date: 2011-02-13 Impact factor: 43.841

Review 6. Biopolymer organization upon confinement.

Authors: D Marenduzzo; C Micheletti; E Orlandini
Journal: J Phys Condens Matter Date: 2010-06-28 Impact factor: 2.333

7. Establishing the design rules for DNA-mediated programmable colloidal crystallization.

Authors: Robert J Macfarlane; Matthew R Jones; Andrew J Senesi; Kaylie L Young; Byeongdu Lee; Jinsong Wu; Chad A Mirkin
Journal: Angew Chem Int Ed Engl Date: 2010-06-21 Impact factor: 15.336

8. Clot contraction: compression of erythrocytes into tightly packed polyhedra and redistribution of platelets and fibrin.

Authors: Douglas B Cines; Tatiana Lebedeva; Chandrasekaran Nagaswami; Vincent Hayes; Walter Massefski; Rustem I Litvinov; Lubica Rauova; Thomas J Lowery; John W Weisel
Journal: Blood Date: 2013-12-13 Impact factor: 22.113

Relevance of packing to colloidal self-assembly.

1. Dense regular packings of irregular nonconvex particles.

2. Why is random close packing reproducible?

3. Phase diagram and structural diversity of a family of truncated cubes: degenerate close-packed structures and vacancy-rich states.

4. Shape-controlled synthesis of gold and silver nanoparticles.

5. Mesophase behaviour of polyhedral particles.

Review 6. Biopolymer organization upon confinement.

7. Establishing the design rules for DNA-mediated programmable colloidal crystallization.

8. Clot contraction: compression of erythrocytes into tightly packed polyhedra and redistribution of platelets and fibrin.

9. Capping Ligand Vortices as "Atomic Orbitals" in Nanocrystal Self-Assembly.

Review 10. Nonspherical noble metal nanoparticles: colloid-chemical synthesis and morphology control.

1. The entropic bond in colloidal crystals.

2. From Precision Colloidal Hybrid Materials to Advanced Functional Assemblies.

3. Identity crisis in alchemical space drives the entropic colloidal glass transition.

4. Statistical reprogramming of macroscopic self-assembly with dynamic boundaries.

5. A theory of entropic bonding.