Staple-shaped particles create reversible strong materials

Hausa

Researchers at the University of Colorado Boulder have developed a material made from staple-shaped particles that can switch between being strong and flexible or falling apart on command.

The team, led by Professor Francois Barthelat, designed particles that tangle together like office staples. This entanglement gives the material both tensile strength and toughness.

Vibrations control the process. Gentle vibrations encourage the particles to interlock, while stronger ones cause them to separate quickly.

PhD student Saeed Pezeshki noted the material demonstrates high strength and toughness at the same time. The findings were published in the Journal of Applied Physics.

Potential applications include recyclable construction materials and swarm robotics. The researchers are now testing designs with additional legs inspired by burrs.

Labaran da ke da alaƙa

Photorealistic close-up of a POMbrane crystalline membrane with 1nm pores for molecular filtration
Hoton da AI ya samar

Nature-inspired “POMbranes” use uniform 1-nanometer pores for ultra-selective molecular filtration

An Ruwaito ta hanyar AI Hoton da AI ya samar An Binciki Gaskiya

Researchers from India and Singapore report a crystalline membrane made from polyoxometalate clusters whose intrinsic openings are about 1 nanometer wide, enabling unusually sharp molecular separations that could help lower energy use in some industrial purification and water-reuse steps.

Rice grains inspire new adaptive smart material

Researchers have found that packed rice grains weaken under rapid compression but remain stronger under slow pressure. This unusual property has been used to create a metamaterial that automatically adjusts its behavior based on the speed of applied forces.

Scientists solve 100-year mystery of reinforced rubber

An Ruwaito ta hanyar AI

Researchers at the University of South Florida have identified the mechanism that makes carbon black particles strengthen rubber, resolving a scientific puzzle that has lasted nearly a century. Their computer simulations reveal how the material resists stretching by effectively fighting against itself.

Science

Mysterious material reveals new state of matter beyond quantum spin liquid

Health

French startup develops polymer liquid to aid nerve healing

Science

String theory emerges from basic physics assumptions in new study

Physicists create first butterfly-shaped ultracold molecule

Researchers have produced an exotic molecule that looks like a butterfly, with electron wings, by combining giant and normal-sized rubidium atoms. The achievement completes a two-decade search for a family of such giant molecules and may enable further advances in quantum science.

Northwestern engineers print artificial neurons that can stimulate living brain cells

An Ruwaito ta hanyar AI An Binciki Gaskiya

Northwestern University researchers report they have printed flexible “artificial neurons” that generate realistic electrical spike patterns and can trigger responses in living mouse brain tissue. The team says the work, published April 15 in Nature Nanotechnology, could help advance brain-machine interfaces and more energy-efficient, brain-inspired computing.

June 05, 2026 18:43

Hidden quantum states discovered in cobalt metal

June 03, 2026 06:01

Discovery reverses direction of turbulent energy flow

May 30, 2026 16:31

Researchers stabilize new phase of matter using silver nanoparticles

May 29, 2026 05:20

Twisted graphene reveals new superconductivity control method

May 26, 2026 03:32

Supercomputer simulations explain formation of cosmic magnetic fields

May 05, 2026 11:27

Researchers create exotic quantum states with timed magnetic fields

April 23, 2026 23:57

RMIT researchers develop nanopillar-textured acrylic film that mechanically inactivates viruses on contact

March 30, 2026 08:01

Scientists find simple liquids fracture like solids under stress

Wannan shafin yana amfani da cookies

Muna amfani da cookies don nazari don inganta shafin mu. Karanta manufar sirri mu don ƙarin bayani.
Ƙi