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Light driven directional mass transport of azo-benzene containing materials for complex tri-dimensional structures on surfaces
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Journal of Material Sciences & Engineering

ISSN: 2169-0022

Open Access

Light driven directional mass transport of azo-benzene containing materials for complex tri-dimensional structures on surfaces


9th World Congress on Materials Science and Engineering

June 12-14, 2017 Rome, Italy

Stefano L Oscurato, Fabio Borbone, Pasqualino Maddalena and Antonio Ambrosio

University of Naples Federico II, Italy
Harvard University, Cambridge, USA

Scientific Tracks Abstracts: J Material Sci Eng

Abstract :

Inspired by nature, in the last years the role of the topography of superficial textures in determining surface functionalities is increasingly recognized and the fabrication of controlled tridimensional textures became a demanding point of material science because of the potential applications in many fields as photonics, functional and smart surfaces. Standard fabrication techniques, including photo-lithography, electron beam and focused ion beam lithography, self-assembly, soft lithography, etc., often require multistep processes in order to realize 3D architectures and the fabricated geometries are rarely further tunable. However, the light-induced mass migration phenomenon arising in photo-responsive azo-benzene containing materials opens to new fabrication approaches. Under illumination, the azo-benzene molecules exhibit photo-isomerization trans-cis-trans cycles. This microscopic motion drives a reorganization of the host material, typically a polymer, in which the molecules are embedded, resulting in a macroscopic material displacement. This material motion is highly directional and occurs in the illuminating light polarization direction. Recently, our group proposed phenomenological models to deterministically predict the topography of the azo-surfaces resulting from lightsurface interaction in different configurations. So the light-driven mass migration can be actually used to fabricate new classes of surface topographies, which can be even further modified once fabricated. Here, we demonstrate the potentiality of this technique by realizing tri-dimensional complex superficial patterns based either on spatially structured illumination light patterns or on reshaping of pre-patterned surface architectures. Spatially modulated intensity patterns are achieved in a versatile way by phase-modulating a laser beam through a computer controlled spatial light modulator, resulting in topography modulation of the azo-surfaces, even with high spatial resolution (Fig. 1a). On the other side, tri-dimensional architectures are obtained by reshaping pristine pre-patterned micron-posts in simple illumination condition. These resulting structures are proven to produce a change in the wetting behavior of the textured surface with a demonstrated controlled directional droplet spreading (Fig. 1b).

Biography :

Stefano L Oscurato has done his MSc in Physics from the University of Naples "Federico II" Italy, and his Master's dissertation was about the development of a holographic scanning microscopy technique. He is doing his Doctoral studies at the University of Naples, supervised by Professor Pasqualino Maddalena and Dr. Antonio Ambrosio. His PhD work is about the use of light-driven mass migration in azobenzene-containing materials for application in photonics, wettability and adhesion.

Email: oscurato@fisica.unina.it

Google Scholar citation report
Citations: 3677

Journal of Material Sciences & Engineering received 3677 citations as per Google Scholar report

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