Motility-Induced Crystallization and Rotating Crystallites [Motilitätsinduzierte Kristallisation und rotierende Kristallite]
Holl, M. P.; Steinberg, A. B.; te Vrugt, M.; Thiele, U.
Forschungsartikel (Zeitschrift) | Peer reviewedZusammenfassung
Active soft matter frequently shows motility-induced phase separation, where self-propelled particles condensate into clusters with an inner liquidlike structure. Such activity may also result in motility-induced crystallization into clusters with an inner crystalline structure. We derive a higher-order active phase-field-crystal model and employ it to study the interplay of passive (i.e., thermodynamic) and active (i.e., motility-induced) condensation or evaporation and crystallization or melting. Stability and morphological phase diagrams indicate the various occurring phase coexistences and transitions, e.g., the destruction of passive clusters in the case of a density-independent effective velocity and the possible creation of active clusters in the case of a density-dependent effective velocity. Finally, simple and complex rotating crystallites are discussed, including states of time-periodic chirality.
Details zur Publikation
Autor*innen der Universität Münster
| Holl, Max Philipp | |
| Steinberg, Alina Barbara | |
| te Vrugt, Michael | |
| Thiele, Uwe |
Promotionen, aus denen die Publikation resultiert
| Musterbildung in Bose-Einstein Kondensaten Promovend*in: Steinberg, Alina Barbara | Betreuer*innen: Thiele, Uwe; Gurevich, Svetlana; Maucher, Fabian Zeitraum: 01.10.2020 - 30.09.2023 Promotionsverfahren erfolgt(e) an: Promotionsverfahren an der Universität Münster | |
| Phase Field Crystal Models for active and passive soft matter Promovend*in: Holl, Max Philipp | Betreuer*innen: Thiele, Uwe; Archer, Andrew J: Zeitraum: bis 01.10.2022 Promotionsverfahren erfolgt(e) an: Promotionsverfahren an der Universität Münster |