Scientists solve 100-year mystery of reinforced rubber

Kiswahili

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.

The team, led by engineering professor David Simmons, conducted 1,500 molecular dynamics simulations that totaled the equivalent of 15 years of computing time. Working with postdoctoral scholar Pierre Kawak and doctoral student Harshad Bhapkar, they showed that carbon black particles limit how much rubber thins when stretched. This forces the material to expand in volume, greatly increasing its stiffness and strength.

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Rice grains inspire new adaptive smart material

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Peking university physicists unveil narwhal waves for light confinement

Imeripotiwa na AI

Researchers at Peking University have discovered narwhal-shaped wavefunctions that trap light at scales far smaller than previously possible using only dielectric materials. The breakthrough, detailed in a 2025 paper, avoids the energy losses common in metal-based approaches. It opens paths to more efficient photonic devices and advanced imaging.

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New manganese compound discovered deep in Earth's mantle

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Researchers stabilize new phase of matter using silver nanoparticles

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Twisted graphene reveals new superconductivity control method

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Researchers reveal why gold stays shiny

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Physicists create first butterfly-shaped ultracold molecule

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

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Light strengthens plant tissues but limits growth in peas

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Scientists stabilize carbene in water, confirming vitamin B1 theory

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