Abstract
The possibility of electrically tuning the scattering of light from surfaces by dynamically varying their properties is desirable for controllable transparency devices and diffusion filters. As a difference from state-of-the-art approaches where scattering is changed isotropically, this paper presents the first smart-material-based technology enabling electrical modulations in a single or multiple directions, which can be selected dynamically. The effect is achieved from thin soft membranes with transparent PEDOT:PSS coatings, which are electrically deformed along a single or multiple axes, using dielectric elastomer actuation. Anisotropic scattering is induced by electrically tuning the formation of directional surface wrinkles. As a proof of concept, a bi-directional device is obtained by overlapping two 90°-shifted mono-directional layers that can be controlled independently. According to the activation of the layers, light can be scattered along either direction, as well as both of them. Prototypes made of an acrylic elastomer were demonstrated with mono- and bi-directional operations. Devices with a window-to-total area ratio of 1:4 also showed a maximum electrical reduction of optical transmittance from 75% to 4%. This functionality and possible extensions to more than two controllable directions suggest applicability as electrically controllable anisotropic light diffusers for dynamic light shaping, as well as tunable transparency surfaces.
Highlights
Smart devices capable of tuning the scattering of light by means of a control voltage are gathering significant interest for various applications, including controllable transparency devices and controllable light diffusing filters [1,2,3]
The most used technologies for such optical devices consist of electrochromic materials [4,5,6] and polymerdispersed liquid crystals (PDLC) [7,8,9,10]
Unlike electrochromic materials, where the operation is based on electrochemical reactions, the dielectric elastomer actuators (DEAs) technology relies on an electrostatic effect, which is intrinsically faster [11,12,13,14,15,16,17,18,19]
Summary
Smart devices capable of tuning the scattering of light by means of a control voltage are gathering significant interest for various applications, including controllable transparency devices (such as dimmable windows and privacy glasses) and controllable light diffusing filters [1,2,3]. As a type of electromechanically active polymer (EAP) actuators [20], DEAs essentially are deformable capacitors made of a dielectric elastomer (DE) membrane, typically consisting of acrylic or silicone elastomers, coated on both sides with deformable electrodes. The latter can be made of transparent materials (including graphene, carbon nanotubes, ionic conductors, silver nanowires or conducting polymers) or not (for example, carbon loaded elastomers or greases) [21]. Devices based on the DEA technology can exhibit large actuation strains, high response speeds, light weight, high resilience, high energy efficiency and no acoustic noise [24,25,26,27,28]
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