Topological interlocking materials and structures represent an innovative design approach in which individual, often geometrically complex, elements are arranged to mutually constrain one another.

Fungi are master engineers capable of building vast networks underground. Now, researchers have harnessed their capabilities to create a living building material that could be a sustainable ...

The new method can determine crystal structures underlying experimental data thus far difficult to analyze. A joint research team led by Yuuki Kubo and Shiji Tsuneyuki of the University of Tokyo has ...

(Nanowerk Spotlight) The materials we interact with every day—whether they are steel, glass, or rubber—have properties like strength, flexibility, or brittleness that stem from their chemical ...

In the future, there could be materials that can reconfigure themselves on demand, adapting their structure and properties like living organisms. A team of Japanese scientists have created a ...

Mesoporous materials are a class of nanomaterials characterized by their highly ordered porous structure with pore sizes ranging from 2 to 50 nanometers. These materials possess large surface areas, ...

A robot chemist just teamed up with an AI brain to create a trove of new materials. Two collaborative studies from Google DeepMind and the University of California, Berkeley, describe a system that ...

A new material may be the key to quickly flag damaged infrastructure. This material offers a way to reduce the manpower required to regularly monitor structures that undergo daily use such as bridges.

iSurface, a project led by Munro Technology, Z Prime, Axalp Technologies AG and researchers from Swiss university of applied sciences FHNW (Fachhochschule Nordwestschweiz), unveiled a new intelligent ...