Projects per year
Abstract
Multicore polymer micelles and aggregates are assemblies that contain several cores. The dual-length-scale compartmentalized solvophobic–solvophilic molecular environment makes them useful for, e.g., advanced drug delivery, high-precision synthesis platforms, confined catalysis, and sensor device applications. However, designing and regulating polymer systems that self-assemble to such morphologies remains a challenge. Using dissipative particle dynamics (DPD) simulations, we demonstrate how simple, three-component linear polymer systems consisting of free solvophilic and solvophobic homopolymers, and di-block copolymers, can self-assemble in solution to form well-defined multicore assemblies. We examine the polymer property range over which multicore assemblies can be expected and how the assemblies can be tuned both in terms of their morphology and structure. For a fixed degree of polymerization, a certain level of hydrophobicity is required for the solvophobic component to lead to formation of multicore assemblies. Additionally, the transition from single-core to multicore requires a relatively high solvophobicity difference between the solvophilic and solvophobic polymer components. Furthermore, if the solvophilic polymer is replaced by a solvophobic species, well-defined multicore–multicompartment aggregates can be obtained. The findings provide guidelines for multicore assemblies’ formation from simple three-component systems and how to control polymer particle morphology and structure.
Original language | English |
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Article number | 2193 |
Number of pages | 17 |
Journal | Polymers |
Volume | 13 |
Issue number | 13 |
DOIs | |
Publication status | Published - 1 Jul 2021 |
MoE publication type | A1 Journal article-refereed |
Keywords
- Block copolymer
- Dissipative particle dynamics
- Multicompartment assembly
- Multicompartment micelle
- Multicore assembly
- Multicore micelle
- Polymer self-assembly
Fingerprint
Dive into the research topics of 'Multicore assemblies from three-component linear homo-copolymer systems: A coarse-grained modeling study'. Together they form a unique fingerprint.Projects
- 4 Finished
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FinnCERES: Competence Center for the Materials Bioeconomy: A Flagship for our Sustainable Future
Mäkelä, K. (Principal investigator)
01/05/2018 → 31/12/2022
Project: Academy of Finland: Other research funding
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Finnish Centre of Excellence in Quantum Technology
Alipour, S. (Project Member), Ala-Nissilä, T. (Principal investigator), Fan, Z. (Project Member), Tuorila, J. (Project Member) & Hirvonen, P. (Project Member)
01/01/2018 → 31/12/2020
Project: Academy of Finland: Other research funding
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PolyDyna: Coarse-Grained Modeling of Translocation and Polymer Dynamics in Nanofluidic Systems
Ala-Nissilä, T. (Principal investigator), Achim, C. (Project Member), Alipour, S. (Project Member), Alcanzare, M. (Project Member), Muhli, H. (Project Member), Seyedheydari, F. (Project Member), Molla, J. (Project Member), Hirvonen, P. (Project Member), Babu, A. (Project Member), Hashemi Petrudi, A. (Project Member), Vadimov, V. (Project Member), Ferreira Sampaio, R. (Project Member), Conley, K. (Project Member) & Fan, Z. (Project Member)
01/09/2017 → 31/12/2021
Project: Academy of Finland: Other research funding
Equipment
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Bioeconomy Research Infrastructure
Seppälä, J. (Manager)
School of Chemical EngineeringFacility/equipment: Facility
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Raw Materials Research Infrastructure
Karppinen, M. (Manager)
School of Chemical EngineeringFacility/equipment: Facility