A team of engineers from RMIT’s Centre for Innovative Structures and Materials utilized biomimicry to develop a super-strong lattice structure that provides enhanced performance compared to ...

Interconnected materials containing networks are ubiquitous in the world around us—rubber, car tires, human and engineered tissues, woven sheets and chain mail armor. Engineers often want these ...

Inspired by the humble deep-sea sponge, RMIT University engineers have developed a new material with remarkable compressive ...

All those sea sponges that live in deep oceans have a secret: their light lattice-like forms are astonishingly stiff and ...

“While most materials get thinner when stretched or fatter when squashed, like rubber, auxetics do the opposite ... Subscribe for FREE The bioinspired lattice structure could work as a steel building ...

“While most materials get thinner when stretched or fatter when squashed, like rubber, auxetics do the ... The bioinspired lattice structure could work as a steel building frame, for example ...

"While most materials get thinner when stretched or fatter when squashed, like rubber, auxetics do the opposite," Ma ... and sports gear or medical applications." The bioinspired lattice structure ...

“While most materials get thinner when stretched or fatter when squashed, like rubber, auxetics do the opposite ... generation sustainable building,” he said. The bioinspired lattice structure could ...

When the scientists ran this model through NASA's Pleiades supercomputer, it spit out a structure for the inner part of the cloud (the most densely populated region, located 1,000 to 10,000 AU ...

(20,21) This paper introduces a novel perspective to control the rate of isoprene skeleton degradation during low-temperature pyrolysis; the study aimed to enhance the quality of the obtained liquid ...