A new, updated account of poroid fungi in North America
Poroid fungi, commonly known as "polypores," are among the most frequently encountered fungi throughout the year because of their large ...
{"id":34496,"date":"2017-05-24T17:30:18","date_gmt":"2017-05-24T16:30:18","guid":{"rendered":"https:\/\/bioengineer.org\/nanoalloys-10-times-as-effective-as-pure-platinum-in-fuel-cells\/"},"modified":"2017-05-24T17:30:18","modified_gmt":"2017-05-24T16:30:18","slug":"nanoalloys-10-times-as-effective-as-pure-platinum-in-fuel-cells","status":"publish","type":"post","link":"https:\/\/bioengineer.org\/nanoalloys-10-times-as-effective-as-pure-platinum-in-fuel-cells\/","title":{"rendered":"Nanoalloys 10 times as effective as pure platinum in fuel cells"},"content":{"rendered":"
(Chalmers University of Technology) A new type of nanocatalyst can result in the long-awaited commercial breakthrough for fuel cell cars. Research results from Chalmers University of Technology and Technical University of Denmark show that it is possible to significantly reduce the need for platinum, a precious and rare metal, by creating a nanoalloy using a new production technique. The technology is also well suited for mass production.<\/p>\n
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