{"id":45118,"date":"2016-04-13T16:28:19","date_gmt":"2016-04-13T20:28:19","guid":{"rendered":"http:\/\/planetsave.com\/?p=45118"},"modified":"2019-07-17T14:58:57","modified_gmt":"2019-07-17T18:58:57","slug":"materials-innovation-future-stronger-lighter-sustainable-materials","status":"publish","type":"post","link":"https:\/\/planetsave.com\/articles\/materials-innovation-future-stronger-lighter-sustainable-materials\/","title":{"rendered":"Materials Innovation: The Future of Stronger, Lighter, more Sustainable Materials"},"content":{"rendered":"
\n\u201cMaterials have always been about enthusiasm. Materials are a dream that we have\u00a0realized. Everything is possible, it\u2019s just that we have to make it happen,\u201d says Mark\u00a0Miodownik, the author behind the popular book Stuff Matters, in the fourth film of\u00a0the Looking Ahead series.<\/em><\/p>\n<\/blockquote>\n
The Age of New Materials<\/h3>\n
Throughout history, materials and advances in material technology have influenced humankind. Now we just might be on the verge of the next shift in this type of technology, enabling products and functions we never believed possible.
\nDemands from industry are requiring that materials be lighter, tougher, thinner, denser and more flexible or rigid, as well as to be heat- and wear-resistant. At the same time, researchers are pushing the boundaries of what we imagine is possible, seeking to improve and enhance existing materials and at the same time come up with completely new materials that, while years away from day-to-day use, take us down entirely new technological pathways.<\/p>\n<\/p>\n
The Sky is the Limit<\/h3>\n
Based on the research we\u2019re seeing today, the field of applied material science is set to move in new, almost science-fiction-like directions. Looming resource scarcity is demanding innovations and out-of-the-box thinking.
\nOn the materials front, composites with such desirable attributes as low weight, high strength and high durability look likely to take a larger market share, and more of these materials will likely be based on renewable resources, as the need for this becomes greater.<\/p>\nThe most promising jewel in this arena is graphene. Only a single atom thick (1 million times thinner than a human hair), but 200 times stronger than steel by weight, extremely flexible, super light and almost transparent with great heat and electricity conductivity. It\u2019s the stuff legends are made of.<\/p>\n
In fact, researchers at Nankai University in Tianjin, China, recently found that a graphene sponge can turn light into energy, thus taking humankind one step closer to a fuel-free spacecraft, one that runs by the light of the sun.<\/p>\n
Heading for the Graphene Revolution<\/h3>\n
Other potential areas of application for graphene range from water purification and energy storage to household goods, computers and other electronics. Meanwhile, although graphene-related patents are increasing by the thousands, widespread industrial adoption of graphene is limited by the expense of producing it \u2013 but that may be about to change.\u00a0Researchers at the University of Glasgow have found a way to produce large sheets of graphene at a cost some 100 times cheaper than the previous production method.<\/p>\n
Synthetic skin, capable of providing sensory feedback to people with limb prostheses, is one of the many possibilities that could grow out of this development. \u201cGraphene could help provide an ultraflexible, conductive surface that could provide people with prosthetics capable of providing sensation in a way that is impossible for even the most advanced prosthetics today,\u201d says Dr. Ravinder Dahiya, who led the research team at the University of\u00a0Glasgow.<\/p>\n
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If it\u2019s Broken, Let it Fix Itself<\/h3>\n
Nanocomposite research is opening up the possibility of materials that fix themselves, much the way the human body heals itself. Researchers at the Beckman Institute\u2019s Autonomous Materials Systems Group at the University of Illinois in the United States are working on fiber-composite materials with self-healing properties that involve the\u00a0integration of healing agents that are released to mix and polymerize when a defect is detected.<\/p>\n