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#materialscience — Public Fediverse posts

Live and recent posts from across the Fediverse tagged #materialscience, aggregated by home.social.

  1. Researchers Unveil ‘MatterChat’: A Bridge for Atomic Structural Vision

    How does Berkeley Lab MatterChat help AI understand atomic structures? This new tool allows AI to analyze 3D physical data for faster material discovery.

    #matterchat, #berkeleylab, #ai, #materialscience, #atomicresearch

    newsletter.tf/berkeley-lab-mat

  2. Researchers at Berkeley Lab created MatterChat to help AI read atomic data. This is a big step forward compared to old AI models that only read text.

    #matterchat, #berkeleylab, #ai, #materialscience, #atomicresearch
    newsletter.tf/berkeley-lab-mat

  3. A novel metamaterial design that transforms flat sheets into smooth, doubly curved 3D shells capable of switching from flexible to rigid load-bearing states on demand.
    #Engineering #MaterialScience #sflorg
    sflorg.com/2026/05/eng05212601

  4. MatterChat: AI Gains Atom-Scale Insight for Material Science

    How does the new MatterChat AI help scientists? It uses atom-scale vision to predict new materials faster for researchers at Berkeley Lab.

    #matterchat, #berkeleylab, #materialscience, #aiinnovation, #scientificresearch

    newsletter.tf/matterchat-ai-pr

  5. Researchers are extracting the naturally occurring, honeycomb-like fiber networks from prickly pear cactus waste to develop sustainable, low-carbon composite building materials.
    #MaterialScience #Engineering #AgriculturalScience #sflorg
    sflorg.com/2026/05/ms05152601.

  6. An innovative, water-based electrically conductive adhesive that functions like traditional solder to join electronic components, but can be easily debonded for efficient recycling.
    #Chemistry #Engineering #MaterialScience #sflorg
    sflorg.com/2026/05/chm05142601

  7. An innovative, water-based electrically conductive adhesive that functions like traditional solder to join electronic components, but can be easily debonded for efficient recycling.
    #Chemistry #Engineering #MaterialScience #sflorg
    sflorg.com/2026/05/chm05142601

  8. An innovative, water-based electrically conductive adhesive that functions like traditional solder to join electronic components, but can be easily debonded for efficient recycling.
    #Chemistry #Engineering #MaterialScience #sflorg
    sflorg.com/2026/05/chm05142601

  9. An innovative, water-based electrically conductive adhesive that functions like traditional solder to join electronic components, but can be easily debonded for efficient recycling.
    #Chemistry #Engineering #MaterialScience #sflorg
    sflorg.com/2026/05/chm05142601

  10. An innovative, water-based electrically conductive adhesive that functions like traditional solder to join electronic components, but can be easily debonded for efficient recycling.
    #Chemistry #Engineering #MaterialScience #sflorg
    sflorg.com/2026/05/chm05142601

  11. Scientists have engineered synthetic organelles using tiny sponge-like particles to transport a team of six proteins into living cells, creating a nanoscale factory that produces therapeutic compounds directly inside the cell.
    #Nanotechnology #Bioengineering #MaterialScience #SyntheticBiology #sflorg
    sflorg.com/2026/05/nt05142601.

  12. Scientists have engineered synthetic organelles using tiny sponge-like particles to transport a team of six proteins into living cells, creating a nanoscale factory that produces therapeutic compounds directly inside the cell.
    #Nanotechnology #Bioengineering #MaterialScience #SyntheticBiology #sflorg
    sflorg.com/2026/05/nt05142601.

  13. Scientists have engineered synthetic organelles using tiny sponge-like particles to transport a team of six proteins into living cells, creating a nanoscale factory that produces therapeutic compounds directly inside the cell.
    #Nanotechnology #Bioengineering #MaterialScience #SyntheticBiology #sflorg
    sflorg.com/2026/05/nt05142601.

  14. Scientists have engineered synthetic organelles using tiny sponge-like particles to transport a team of six proteins into living cells, creating a nanoscale factory that produces therapeutic compounds directly inside the cell.
    #Nanotechnology #Bioengineering #MaterialScience #SyntheticBiology #sflorg
    sflorg.com/2026/05/nt05142601.

  15. Scientists have engineered synthetic organelles using tiny sponge-like particles to transport a team of six proteins into living cells, creating a nanoscale factory that produces therapeutic compounds directly inside the cell.
    #Nanotechnology #Bioengineering #MaterialScience #SyntheticBiology #sflorg
    sflorg.com/2026/05/nt05142601.

  16. A novel methodology for deterministically moving tens of thousands of individual atoms within the three-dimensional crystalline lattice of a solid material at room temperature.
    #MaterialScience #QuantumScience #Nanotechnology #SolidStatePhysics #sflorg
    sflorg.com/2026/05/ms05132601.

  17. A novel methodology for deterministically moving tens of thousands of individual atoms within the three-dimensional crystalline lattice of a solid material at room temperature.
    #MaterialScience #QuantumScience #Nanotechnology #SolidStatePhysics #sflorg
    sflorg.com/2026/05/ms05132601.

  18. A novel methodology for deterministically moving tens of thousands of individual atoms within the three-dimensional crystalline lattice of a solid material at room temperature.
    #MaterialScience #QuantumScience #Nanotechnology #SolidStatePhysics #sflorg
    sflorg.com/2026/05/ms05132601.

  19. A novel methodology for deterministically moving tens of thousands of individual atoms within the three-dimensional crystalline lattice of a solid material at room temperature.
    #MaterialScience #QuantumScience #Nanotechnology #SolidStatePhysics #sflorg
    sflorg.com/2026/05/ms05132601.

  20. A novel methodology for deterministically moving tens of thousands of individual atoms within the three-dimensional crystalline lattice of a solid material at room temperature.
    #MaterialScience #QuantumScience #Nanotechnology #SolidStatePhysics #sflorg
    sflorg.com/2026/05/ms05132601.

  21. A non-toxic, highly stretchable thermoplastic developed from #cannabidiol (CBD) found in #hemp plants, functioning as a sustainable replacement for petroleum-based plastics like polyethylene terephthalate (PET).
    #Chemistry #MaterialScience #sflorg
    sflorg.com/2026/05/chm05132601

  22. A non-toxic, highly stretchable thermoplastic developed from #cannabidiol (CBD) found in #hemp plants, functioning as a sustainable replacement for petroleum-based plastics like polyethylene terephthalate (PET).
    #Chemistry #MaterialScience #sflorg
    sflorg.com/2026/05/chm05132601

  23. A non-toxic, highly stretchable thermoplastic developed from #cannabidiol (CBD) found in #hemp plants, functioning as a sustainable replacement for petroleum-based plastics like polyethylene terephthalate (PET).
    #Chemistry #MaterialScience #sflorg
    sflorg.com/2026/05/chm05132601

  24. A non-toxic, highly stretchable thermoplastic developed from #cannabidiol (CBD) found in #hemp plants, functioning as a sustainable replacement for petroleum-based plastics like polyethylene terephthalate (PET).
    #Chemistry #MaterialScience #sflorg
    sflorg.com/2026/05/chm05132601

  25. A non-toxic, highly stretchable thermoplastic developed from #cannabidiol (CBD) found in #hemp plants, functioning as a sustainable replacement for petroleum-based plastics like polyethylene terephthalate (PET).
    #Chemistry #MaterialScience #sflorg
    sflorg.com/2026/05/chm05132601

  26. Gold nanoparticles coated with specific organic molecules can dynamically reorganize their large-scale two-dimensional arrangements at an air/water interface, exhibiting fluid, responsive behavior.
    #Nanotechnology #MaterialScience #Chemistry #sflorg
    sflorg.com/2026/05/nt05132601.

  27. Gold nanoparticles coated with specific organic molecules can dynamically reorganize their large-scale two-dimensional arrangements at an air/water interface, exhibiting fluid, responsive behavior.
    #Nanotechnology #MaterialScience #Chemistry #sflorg
    sflorg.com/2026/05/nt05132601.

  28. Gold nanoparticles coated with specific organic molecules can dynamically reorganize their large-scale two-dimensional arrangements at an air/water interface, exhibiting fluid, responsive behavior.
    #Nanotechnology #MaterialScience #Chemistry #sflorg
    sflorg.com/2026/05/nt05132601.

  29. Gold nanoparticles coated with specific organic molecules can dynamically reorganize their large-scale two-dimensional arrangements at an air/water interface, exhibiting fluid, responsive behavior.
    #Nanotechnology #MaterialScience #Chemistry #sflorg
    sflorg.com/2026/05/nt05132601.

  30. Gold nanoparticles coated with specific organic molecules can dynamically reorganize their large-scale two-dimensional arrangements at an air/water interface, exhibiting fluid, responsive behavior.
    #Nanotechnology #MaterialScience #Chemistry #sflorg
    sflorg.com/2026/05/nt05132601.

  31. Researchers Observe "Ferrons," Polarization Waves with Potential Upsides

    Scientists found new 'ferrons' polarization waves. This could help quantum computing and phones. Learn what it means for technology.

    #Ferrons, #PolarizationWaves, #QuantumComputing, #Telecommunications, #MaterialScience

    newsletter.tf/scientists-find-

  32. Physicists Discover Previously Unknown Crystal Forged During Manhattan Project’s Trinity Test

    America’s first plutonium implosion test—its first detonated nuclear bomb—left the 100-foot (30-meter) tower that held it aloft, including…
    #NewsBeep #News #US #USA #UnitedStates #UnitedStatesOfAmerica #Science #crystals #ManhattanProject #MaterialScience #Nuclearweapons
    newsbeep.com/us/637282/

  33. Silk-amyloid-mussel (SAM) protein hybrids are bioengineered materials produced by genetically modified microbes that serve as a fully recyclable, biodegradable alternative to synthetic textiles.
    #SyntheticBiology #MaterialScience #Engineering #Environmental #sflorg
    sflorg.com/2026/05/sybi0510260

  34. Silk-amyloid-mussel (SAM) protein hybrids are bioengineered materials produced by genetically modified microbes that serve as a fully recyclable, biodegradable alternative to synthetic textiles.
    #SyntheticBiology #MaterialScience #Engineering #Environmental #sflorg
    sflorg.com/2026/05/sybi0510260

  35. Silk-amyloid-mussel (SAM) protein hybrids are bioengineered materials produced by genetically modified microbes that serve as a fully recyclable, biodegradable alternative to synthetic textiles.
    #SyntheticBiology #MaterialScience #Engineering #Environmental #sflorg
    sflorg.com/2026/05/sybi0510260

  36. Silk-amyloid-mussel (SAM) protein hybrids are bioengineered materials produced by genetically modified microbes that serve as a fully recyclable, biodegradable alternative to synthetic textiles.
    #SyntheticBiology #MaterialScience #Engineering #Environmental #sflorg
    sflorg.com/2026/05/sybi0510260

  37. Silk-amyloid-mussel (SAM) protein hybrids are bioengineered materials produced by genetically modified microbes that serve as a fully recyclable, biodegradable alternative to synthetic textiles.
    #SyntheticBiology #MaterialScience #Engineering #Environmental #sflorg
    sflorg.com/2026/05/sybi0510260

  38. University of Hong Kong researchers develop a corrosion-resistant super steel to enable green hydrogen production from seawater

    The new material utilizes a double-protection mechanism to withstand the harsh conditions required for green hydrogen production from seawater.

    newsnews.ai/article/university

  39. 🫁‘Materials that implants are made of often cause inflammation or tissue damage.’

    Prof. of Polymer Science Marleen Kamperman & research team at the UG & UMCG are developing softer materials for stents and valves, as well as less invasive means to insert them using magnets.🧲

    Curious? Read more 👇
    🔗 rug.nl/fse/news/science-in-foc

    🧪 #SciComm #ScienceNewsroom #materialscience #lungs #biomaterials #biology #research #science #engineering #scientistsOnMastodon
    @universityofgroningen @umcgresearch
    #HTRIC

  40. 🫁‘Materials that implants are made of often cause inflammation or tissue damage.’

    Prof. of Polymer Science Marleen Kamperman & research team at the UG & UMCG are developing softer materials for stents and valves, as well as less invasive means to insert them using magnets.🧲

    Curious? Read more 👇
    🔗 rug.nl/fse/news/science-in-foc

    🧪 #SciComm #ScienceNewsroom #materialscience #lungs #biomaterials #biology #research #science #engineering #scientistsOnMastodon
    @universityofgroningen @umcgresearch
    #HTRIC

  41. 🫁‘Materials that implants are made of often cause inflammation or tissue damage.’

    Prof. of Polymer Science Marleen Kamperman & research team at the UG & UMCG are developing softer materials for stents and valves, as well as less invasive means to insert them using magnets.🧲

    Curious? Read more 👇
    🔗 rug.nl/fse/news/science-in-foc

    🧪 #SciComm #ScienceNewsroom #materialscience #lungs #biomaterials #biology #research #science #engineering #scientistsOnMastodon
    @universityofgroningen @umcgresearch
    #HTRIC

  42. 🫁‘Materials that implants are made of often cause inflammation or tissue damage.’

    Prof. of Polymer Science Marleen Kamperman & research team at the UG & UMCG are developing softer materials for stents and valves, as well as less invasive means to insert them using magnets.🧲

    Curious? Read more 👇
    🔗 rug.nl/fse/news/science-in-foc

    🧪 #SciComm #ScienceNewsroom #materialscience #lungs #biomaterials #biology #research #science #engineering #scientistsOnMastodon
    @universityofgroningen @umcgresearch
    #HTRIC

  43. 🫁‘Materials that implants are made of often cause inflammation or tissue damage.’

    Prof. of Polymer Science Marleen Kamperman & research team at the UG & UMCG are developing softer materials for stents and valves, as well as less invasive means to insert them using magnets.🧲

    Curious? Read more 👇
    🔗 rug.nl/fse/news/science-in-foc

    🧪 #SciComm #ScienceNewsroom #materialscience #lungs #biomaterials #biology #research #science #engineering #scientistsOnMastodon
    @universityofgroningen @umcgresearch
    #HTRIC

  44. Terahertz Circuits Edge Closer With New Light-Bending Material

    How does lead iodide help make faster microcircuits? Learn how this new material improves data speed and lowers energy use for future technology.

    #terahertz, #microcircuits, #materialscience, #techupdate, #futuretech

    newsletter.tf/lead-iodide-tera

  45. Scientists found that lead iodide can bend light to make computers faster. This new method is much cheaper than older ways to build light-based circuits.

    #terahertz, #microcircuits, #materialscience, #techupdate, #futuretech
    newsletter.tf/lead-iodide-tera

  46. Nematic Crystals Exhibit Paradoxical Order-Disorder State

    How do nematic crystals show order and disorder at the same time? Learn about the May 2026 discovery of nematoelasticity and its role in superconductivity.

    #physicsnews, #nematiccrystals, #superconductivity, #materialscience, #quantumphysics

    newsletter.tf/nematoelasticity