New research from Concordia University now brings the future of fashion into focus by taking a closer look at the next quantum leap in textile design: computerized fabrics that change their colour and their shape in response to movement.
Joanna Berzowska, professor and chair of the Department of Design and Computation Arts at Concordia, has developed interactive electronic fabrics that harness power directly from the human body, store that energy, and then use it to change the garments’ visual properties.
The major innovation of this research project is the ability to embed these electronic or computer functions within the fibre itself: rather than being attached to the textile, the electronic components are woven into these new composite fibres. The fibres consist of multiple layers of polymers, which, when stretched and drawn out to a small diameter, begin to interact with each other. The fabric, produced in collaboration with the École Polytechnique’s Maksim Skorobogatiy, represent a significant advance in the development of “smart textiles.”
Although it’s not yet possible to manufacture clothing with the new composite fibres, Berzowska worked with fashion designers to create conceptual prototypes that can help us visualize how such clothing might look and behave. “We won’t see such garments in stores for another 20 or 30 years, but the practical and creative possibilities are exciting,” says Berzowska. Imagine a dress that changes shape and colour on its own, or a shirt that can capture the energy from human movement and use it to charge an iPhone.
There would also be a performative aspect to wearing such garments, whose dramatic transformations may or may not be controlled by the wearer. This research raises interesting questions about human behaviour relative to fashion and computers. What would it mean to wear a piece of clothing with “a mind of its own,” that cannot be consciously controlled? How much intimate contact with computers do we really want?
This story is reprinted from material from Concordia University, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.