This research intends to test the applicability of auxetic textiles in architecture. Auxetic materials exhibit a negative Poisson ratio; a unique characteristic that allows them to expand in all directions when stretched, opposite of the way typical materials react to the same stimulus. Auxetic behavior in materials is being studied at a range of scales and has proven to hold great potential for various applications that require flexibility and stability under loading.
Research Trajectory A is based on the conceit that auxetic behavior harnesses great potential to advance the performance of contemporary tensioned membrane materials. Research Trajectory B intends to investigate the architectural and structural potentials of helical auxetic yarns (HAY) as a component in fiber-reinforced composite materials. This research is proposed with confidence that an interdisciplinary study of HAY-reinforced composites may result in novel, customizable sheet materials that are structurally and environmentally resilient.
Nick Bruscia (director) with assistance by Zack Fields, Frank Kraemer, Jelani Lowe, and Kevin Turner. Industry consultation: Advanced Fabric Technologies.
This research is supported by the Nohmura Foundation for Membrane Structure’s Technology.
Customizable Workflows for Multi-axis Waterjet Machining
Influenced by the role of representation in the design and fabrication process, this research aims to develop a more agile and adaptive workflow between digital models and contemporary manufacturing techniques.
False Positive
A mobile performance and workshop that enacts a surveillance conspiracy engaging the public in an intimate, techno-political conversation with the mobile technologies on which they depend.
Disclinations in Self-Reactive Surfaces
This research explores the topological and structural properties of disclinations applied to elastic sheets and suggests their potential at an architectural scale.