## Patchy particles by self-assembly of star copolymers on a spherical substrate: Thomson solutions in a geometric problem with a color constraint

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**Patchy particles by self-assembly of star copolymers on a spherical substrate : Thomson solutions in a geometric problem with a color constraint.** / Hain, Tobias M.; Schröder-Turk, Gerd E.; Kirkensgaard, Jacob J.K.

Research output: Contribution to journal › Journal article › peer-review

#### Harvard

*Soft Matter*, vol. 15, no. 46, pp. 9394-9404. https://doi.org/10.1039/c9sm01460h

#### APA

*Soft Matter*,

*15*(46), 9394-9404. https://doi.org/10.1039/c9sm01460h

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#### RIS

TY - JOUR

T1 - Patchy particles by self-assembly of star copolymers on a spherical substrate

T2 - Thomson solutions in a geometric problem with a color constraint

AU - Hain, Tobias M.

AU - Schröder-Turk, Gerd E.

AU - Kirkensgaard, Jacob J.K.

PY - 2019

Y1 - 2019

N2 - Confinement or geometric frustration is known to alter the structure of soft matter, including copolymeric melts, and can consequently be used to tune structure and properties. Here we investigate the self-assembly of ABC and ABB 3-miktoarm star copolymers confined to a spherical shell using coarse-grained dissipative particle dynamics simulations. In bulk and flat geometries the ABC stars form hexagonal tilings, but this is topologically prohibited in a spherical geometry which normally is alleviated by forming pentagonal tiles. However, the molecular architecture of the ABC stars implies an additional 'color constraint' which only allows even tilings (where all polygons have an even number of edges) and we study the effect of these simultaneous constraints. We find that both ABC and ABB systems form spherical tiling patterns, the type of which depends on the radius of the spherical substrate. For small spherical substrates, all solutions correspond to patterns solving the Thomson problem of placing mobile repulsive electric charges on a sphere. In ABC systems we find three coexisting, possibly different tilings, one in each color, each of them solving the Thomson problem simultaneously. For all except the smallest substrates, we find competing solutions with seemingly degenerate free energies that occur with different probabilities. Statistically, an observer who is blind to the differences between B and C can tell from the structure of the A domains if the system is an ABC or an ABB star copolymer system.

AB - Confinement or geometric frustration is known to alter the structure of soft matter, including copolymeric melts, and can consequently be used to tune structure and properties. Here we investigate the self-assembly of ABC and ABB 3-miktoarm star copolymers confined to a spherical shell using coarse-grained dissipative particle dynamics simulations. In bulk and flat geometries the ABC stars form hexagonal tilings, but this is topologically prohibited in a spherical geometry which normally is alleviated by forming pentagonal tiles. However, the molecular architecture of the ABC stars implies an additional 'color constraint' which only allows even tilings (where all polygons have an even number of edges) and we study the effect of these simultaneous constraints. We find that both ABC and ABB systems form spherical tiling patterns, the type of which depends on the radius of the spherical substrate. For small spherical substrates, all solutions correspond to patterns solving the Thomson problem of placing mobile repulsive electric charges on a sphere. In ABC systems we find three coexisting, possibly different tilings, one in each color, each of them solving the Thomson problem simultaneously. For all except the smallest substrates, we find competing solutions with seemingly degenerate free energies that occur with different probabilities. Statistically, an observer who is blind to the differences between B and C can tell from the structure of the A domains if the system is an ABC or an ABB star copolymer system.

U2 - 10.1039/c9sm01460h

DO - 10.1039/c9sm01460h

M3 - Journal article

C2 - 31595280

AN - SCOPUS:85075754492

VL - 15

SP - 9394

EP - 9404

JO - Journal of Materials Chemistry

JF - Journal of Materials Chemistry

SN - 1744-683X

IS - 46

ER -

ID: 231592479