Additive manufacturing (AM) has emerged as a disruptive digital manufacturing technology.
However, its broad adoption in industry is still hindered by high entry barriers of design for …

The rapid progress of advanced manufacturing, multidisciplinary integration and artificial
intelligence has ushered in a new era of technological development in the design of …

Designing and printing metamaterials with customizable architectures enables the
realization of unprecedented mechanical behaviors that transcend those of their constituent …

Biological materials relying on hierarchically ordered architectures inspire the emergence of
advanced composites with mutually exclusive mechanical properties, but the efficient …

For several industries, the traditional manufacturing processes are time-consuming and
uneconomical due to the absence of the right tool to produce the products. In a couple of …

The emerging capability to 3D print a diverse palette of functional inks will enable the mass
democratization of patient-specific wearable devices and smart biomedical implants for …

Metamaterials are artificial materials designed to exhibit effective material parameters that
go beyond those found in nature. Composed of unit cells with rich designability that are …

While additive manufacturing (AM) has facilitated the production of complex structures, it has
also highlighted the immense challenge inherent in identifying the optimum AM structure for …

Biomaterials display microstructures that are geometrically irregular and functionally
efficient. Understanding the role of irregularity in determining material properties offers a …

Recent advances in computational design and 3D printing enable the fabrication of polymer
lattices with high strength‐to‐weight ratio and tailored mechanics. To date, 3D lattices …