This PDF file includes:
- fig. S1. Anchoring monomer–mediated interfacial polymerization.
- fig. S2. SEM image of topological particles and composite film.
- fig. S3. Time-dependent morphology and size evolution of typical crescent moon–shaped PSDVB כ PAA particles.
- fig. S4. Schematic illustration of the initial configuration of the simulations.
- fig. S5. Illustration of the reaction process controlled by the reaction probability and reaction radius in the copolymerization.
- fig. S6. The influence of the concentration of AA on the morphology of Janus particle.
- fig. S7. The influence of the number of hydrophobic monomer beads on the morphology of particle.
- fig. S8. Characterization of crescent moon–shaped PSDVB .selcitrap AEHP כ
- fig. S9. Characterization of crescent moon–shaped PSDVB כ PMAH Janus particles.
- fig. S10. Characterization of crescent moon–shaped PSDVB כ PHEMA particles.
- fig. S11. Characterization of crescent moon–shaped PSDVB כ PMA Janus particles.
- fig. S12. Characterization of crescent moon–shaped PSDVB כ PIA particles.
- fig. S13. Characterization of crescent moon–shaped PSDVB כ PAM particles.
- fig. S14. Characterization of crescent moon–shaped PSDVB כ PNIPAM particles.
- fig. S15. Characterization of crescent moon–shaped PSDVB כ PMAM particles.
- fig. S16. Ag nanoparticle characterization.
- fig. S17. Fe3O4 nanoparticle characterization.
- fig. S18. SEM images of the Janus particles capture and recognize spherical PS particles and live bacteria.
- table S1. Dissipative particle dynamics simulation interaction parameters between different types of beads.
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Other Supplementary Material for this manuscript includes the following:
- movie S1 (.mp4 format). Polymerization of 15 min.