Ultrathin 3-D-printed films convert energy of one form into another, MIT News

MIT researchers have developed a 3-D printing technique to create, at room temperature, piezoelectric ultrathin ceramic films capable of high frequency gigahertz-level actuation. The films could enable high-performance flexible electronics and high-sensitivity biosensing.

3D printed nanomaterial could replace kevlar and steel for bulletproof armor - 3D Printing Industry

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3D Printed Formwork for Concrete: State-of-the-Art, Opportunities, Challenges, and Applications

The Superpowers of Super-Thin Materials - The New York Times

How MIT Is Revolutionizing Electronics With 3D-Printed Solenoids

MIT's superthin solar cells convert any surface into a power source

Materials, Free Full-Text

How MIT Is Revolutionizing Electronics With 3D-Printed Solenoids

Ultrathin 3-D-printed films convert energy of one form into another, MIT News

MIT.nano on LinkedIn: New programmable materials can sense their own movements

3D printed nanomaterial could replace kevlar and steel for bulletproof armor - 3D Printing Industry

Particle robots mimic biological stochastic processes – Physics World

Advanced Functional Materials: Vol 25, No 5