Abstract
Stimuli-responsive microstructures are critical to create adaptable systems in soft robotics and biosciences. For such applications, the materials must be compatible with aqueous environments and enable the manufacturing of three-dimensional structures. Poly(N-isopropylacrylamide) (pNIPAM) is a well-established polymer, exhibiting a substantial response to changes in temperature close to its lower critical solution temperature. To create complex actuation patterns, materials that react differently with respect to a stimulus are required. Here, we introduce functional three-dimensional hetero-microstructures based on pNIPAM. By variation of the local exposure dose in three-dimensional laser lithography, we demonstrate that the material parameters can be altered on demand in a single resist formulation. We explore this concept for sophisticated three-dimensional architectures with large-amplitude and complex responses. The experimental results are consistent with numerical calculations, able to predict the actuation response. Furthermore, a spatially controlled response is achieved by inducing a local temperature increase by two-photon absorption of focused light.
Highlights
Stimuli-responsive microstructures are critical to create adaptable systems in soft robotics and biosciences
The local properties in a threedimensional (3D) microstructure can be tailored by the local exposure dose during 3D laser lithography, opening the door to 3D hetero-microstructures from a single photoresist
The second advantage of the present work is that a local temperature increase and the actuation can be induced by two-photon absorption of focused light
Summary
Stimuli-responsive microstructures are critical to create adaptable systems in soft robotics and biosciences For such applications, the materials must be compatible with aqueous environments and enable the manufacturing of three-dimensional structures. By variation of the local exposure dose in three-dimensional laser lithography, we demonstrate that the material parameters can be altered on demand in a single resist formulation We explore this concept for sophisticated three-dimensional architectures with largeamplitude and complex responses. The second advantage of the present work is that a local temperature increase and the actuation can be induced by two-photon absorption of focused light. This aspect potentially allows for initiating local responses in three dimensions, i.e., not just on surfaces and inside of 3D structures
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