6533b82afe1ef96bd128b73e
RESEARCH PRODUCT
Programmable Surface Architectures Derived from Hybrid Polyoxometalate-Based Clusters
De-liang LongChullikkattil P. PradeepAlessandro LuzioLeroy CroninMali H. RosnesBruno PignataroChiara MusumeciYu-fei SongHaralampos N. Mirassubject
Materials scienceSiliconSolid surfaceDrop (liquid)chemistry.chemical_elementNanotechnologySurface energySurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsHigh surfaceGeneral EnergychemistryChemical physicsPolyoxometalateNanodotDewettingPhysical and Theoretical Chemistrydescription
The exploration of the self-organization of a range of the polyoxometalate-based molecular structures reveals a diverse range of surface patterns and morphologies on solid substrates of technological interest, including methylated and hydroxylated silicon surfaces (namely, SiCH3 and SiOH). By exploiting the interplay between the intrinsic molecular properties and the surface chemistry as well as dynamic spatiotemporal phenomena (e.g., dewetting), we show that these systems can yield 0D, 2D, and 3D architectures via solution deposition at the solid surface, including nanodots, discs, lamellas, porous networks, and layer-by-layer assemblies. In general, we observed that layer-by-layer growth is a common feature on low surface energy SiCH3. In addition, the polyoxometalate derived architectures are able to effectively modulate the drop spreading dynamics on high surface energy SiOH, so that dewetting induces the formation of nanodots from dilute solutions of the precursor POM hybrid, whereas using high conce...
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2011-02-25 | The Journal of Physical Chemistry C |