# Automated Plasmon‐Selective Laser Writing in Mesoporous Thin Films Through Decoupling of the Initiator Absorption and Plasmon Wavelength

**Authors:** Marius Kirsch, Robert Lehn, Steffen Paech, Annette Andrieu‐Brunsen

PMC · DOI: 10.1002/smsc.202500435 · Small Science · 2026-03-03

## TL;DR

This paper introduces a method to precisely control polymerization in mesoporous films using plasmon-selective laser writing, enabling advanced applications in sensing and energy.

## Contribution

The novel approach decouples plasmon wavelength from initiator absorption, enabling automated, high-precision polymer placement in mesopores.

## Key findings

- Au nanospheres enable plasmon-induced polymerization with high reactivity and photoiniferter stability.
- Wavelength separation suppresses radiative interactions, allowing plasmon-selective polymerization.
- Plasmon-selective laser writing achieves lateral polymer functionalization in mesoporous membranes.

## Abstract

Enhancing nanopore functionalization precision is relevant to advance future‐relevant technologies such as molecular sensing, separation, catalysis, and energy conversion. An interesting approach for high‐resolution polymerization is to use nanoscale light sources like surface plasmons. To design polymer functionalization in artificial mesopores, Au nanospheres (AuNSs) are implemented into mesoporous silica thin films, harnessing their plasmon for visible‐light near‐field‐induced polymerization initiation. AuNSs are incorporated at defined layer height, pursuing local placement of polymer along the pore depth. Using photoiniferter as photoreactive initiator for reversible‐addition‐fragmentation chain‐transfer (RAFT) polymerization requires demarcated photoreactivity of both moieties, the AuNSs and the photoiniferter. A high reactivity of AuNSs concomitant to the photostability of the photoiniferter is observed. The wavelength‐dependence of the polymerization initiation is investigated, focusing on wavelength separation of iniferter absorption and plasmon generation. Wavelength‐dependent cooperativity effects between AuNSs, the photoiniferter, and the photocatalyst are explored to understand potential radiative and nonradiative polymerization induction mechanisms of the plasmon‐induced polymerization. Ultimately, plasmon‐selective polymerization is integrated into direct laser writing, affording precise lateral polymer functionalization of mesoporous membranes. Aiming at further miniaturized polymer functionalization, a strategy to attain spatial control over polymer placement in an automated process, paving the way to directed ionic movement through mesoporous membranes, is provided.

Plasmon‐selective direct laser writing is demonstrated in mesoporous silica thin films containing plasmonic Au nanospheres. The key to attain plasmon‐selective polymerization is decoupling the plasmon wavelength from the absorption profile of coreactants, hence suppressing mutual radiative interactions. Iniferters, photostable at the incident wavelength, enhance the polymerization while coreactants photoreactive under identical conditions override the plasmon‐selectivity.© 2026 WILEY‐VCH GmbH

## Linked entities

- **Chemicals:** doxorubicin (PubChem CID 31703)

## Full-text entities

- **Genes:** CFI (complement factor I) [NCBI Gene 3426] {aka AHUS3, ARMD13, C3BINA, C3b-INA, FI, IF}
- **Chemicals:** HCl (MESH:D006851), H (MESH:D006859), copper (MESH:D003300), carbon disulfide (MESH:D002246), Ag (MESH:D012834), methacrylate (MESH:D008689), Eosin Y (MESH:D004801), 13C (MESH:C000615229), ZnTPP (MESH:C076448), 3-aminopropyldimethylmethoxysilane (MESH:C543126), cyclohexane (MESH:C506365), DMSO (MESH:D004121), ethanol (MESH:D000431), CO2 (MESH:D002245), water (MESH:D014867), 4-methoxyphenol (MESH:C009760), magnesium sulfate (MESH:D008278), N (MESH:D009584), F127 (MESH:C078661), Hi (MESH:D006639), toluene (MESH:D014050), sodium sulfate (MESH:C012036), Alexa Fluor 488 (MESH:C000711379), acetone (MESH:D000096), oil (MESH:D009821), Polymer (MESH:D011108), C (MESH:D002244), polyelectrolyte (MESH:D000071228), (3-aminopropyl)triethoxysilane (MESH:C477625), amine (MESH:D000588), n-heptane (MESH:C028618), TEOS (MESH:C040733), Au (MESH:D006046), He (MESH:D006371), S (MESH:D013455), 3H (MESH:D014316), ZnSe (MESH:C044696), EDC hydrochloride (MESH:C000613388), MMA (MESH:D020366), trithiocarbonate (MESH:C013321), metal (MESH:D008670), 2H (MESH:D003903), AuNS (-), Si (MESH:D012825), ethyl acetate (MESH:C007650), poly([2-(methacryloyloxy)ethyl]trimethylammonium chloride) (MESH:C401965), PTFE (MESH:D011138), Na (MESH:D012964), O (MESH:D010100), [2-(Methacryloyloxy)ethyl]trimethylammonium chloride (MESH:C120889), Pluronic F127 (MESH:D020442), 4-cyano-4-[(dodecylsulfanylthiocarbonyl)sulfanyl]pentanoic acid (MESH:C000709520), SiO2 (MESH:D012822), Hg (MESH:D008628), sodium citrate (MESH:D000077559)

## Full text

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## Figures

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## References

73 references — full list in the complete paper: https://tomesphere.com/paper/PMC12955915/full.md

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Source: https://tomesphere.com/paper/PMC12955915