All posts tagged: Metamaterial

3D-printed “metamaterial” is stronger than anything in nature

3D-printed “metamaterial” is stronger than anything in nature

Published by skeptic

Using lasers and metal powder, Australian scientists have created a super strong, super lightweight new “metamaterial” — but they got the idea for this sci fi-sounding creation from plants. The challenge: Materials that are strong yet lightweight, such as carbon fiber and graphene, are used to make everything from medical implants to airships, and developing ones with ever greater “strength-to-weight ratios” is the goal of many material scientists. In pursuit of that goal, some have turned to nature, looking for ways to replicate in metal the hollow lattice structures, like those in the Victoria water lily, that make some plants remarkably strong. “These two elements together show strength and lightness never before seen together in nature.” Ma Qian What they’ve been able to create so far using available manufacturing techniques have fallen short, though — an uneven distribution of load stress is a major reason these synthetic materials don’t turn out as strong as their natural counterparts. “Ideally, the stress in all complex cellular materials should be evenly spread,” said Ma Qian, a distinguished professor of advanced manufacturing and materials at …

Groundbreaking titanium alloy “Metamaterial” revolutionizes aerospace technologies

Groundbreaking titanium alloy “Metamaterial” revolutionizes aerospace technologies

Published by skeptic

A groundbreaking metamaterial engineered with unique electromagnetic properties not found in nature, has been developed from a commonly used titanium alloy. PhD candidate Jordan Noronha holding a sample of the new titanium lattice structure 3D printed in cube form. (CREDIT: RMIT) A groundbreaking metamaterial engineered with unique electromagnetic properties not found in nature, has been developed from a commonly used titanium alloy. Despite its conventional origin, this material boasts exceptional strength due to its innovative lattice structure, surpassing existing alloys in aerospace applications by 50 percent. Inspired by the robustness of natural structures like Victoria water lilies and organ-pipe corals, researchers sought to replicate their strength and lightness. Historically, mimicking such cellular structures in artificial materials has proven challenging due to manufacturing constraints and uneven load distribution. Distinguished Professor Ma Qian highlighted this issue, noting that conventional cellular materials often distribute stress unevenly, weakening the structure. However, leveraging advancements in metal 3D printing, the team devised a novel lattice design that evenly disperses stress, mitigating weak points. “We designed a hollow tubular lattice structure with …

A 3D-printed titanium ‘metamaterial’ design solved a longtime engineering issue

A 3D-printed titanium ‘metamaterial’ design solved a longtime engineering issue

Published by skeptic

Cellular structures made from metal alloys could strengthen everything from bone implants to rocket parts—if they didn’t keep cracking under pressure. Researchers have so far spent years attempting to solve for uneven weight distribution issues across these artificial “metamaterials” to little success. As detailed in a recent study published in Advanced Materials, however, a team at Australia’s RMIT University appears to have finally figured out the solution after drawing inspiration from plants and coral, with some help from a cutting-edge 3D-printing tool. Using a common titanium alloy, engineers manufactured latticelike structures composed of hollow struts—each imbued with an additional, thin band running throughout it. According to Ma Qian, an RMIT Distinguished Professor of advanced manufacturing and study co-author, the team combined “two complementary lattice structures to evenly distribute stress, we avoid the weak points where stress normally concentrates.” Compression testing shows (left) stress concentrations in red and yellow on the hollow strut lattice, while (right) the double lattice structure spreads stress more evenly to avoid hot spots. Credit: RMIT “These two elements together show strength …