Category Physics

Akihiro Nomura, Kimihiko Ito, Yoshimi Kubo. CNT Sheet Air Electrode for the Development of Ultra-High Cell Capacity in Lithium-Air Batteries. Scientific Reports, 2017; 7: 45596 DOI: 10.1038/srep45596

A NIMS team led by Yoshimi Kubo and Akihiro Nomura, team leader and researcher, respectively, Lithium Air Battery Specially Promoted Research Team, C4GR-GREEN, developed lithium-air batteries with very high electric storage capacity 15X greater than the capacity of conventional lithium-ion batteries using carbon nanotubes (CNT) as an air electrode material. Demand for rechargeable batteries is expected to increase rapidly as electric vehicle power sources and joint sources of household electricity with solar cells.

The current lithium-ion batteries have advantages of being compact, producing h...

Nelson Sepulveda is a nanotechnology researcher and associate professor of engineering at Michigan State University. Credit: Michigan State University

A paper-thin, flexible device created at Michigan State University not only can generate energy from human motion, it can act as a loudspeaker and microphone as well, nanotechnology researchers report in the May 16 edition of Nature Communications. The audio breakthrough could eventually lead to such consumer products as a foldable loudspeaker, a voice-activated security patch for computers and even a talking newspaper...

A custom chamber built by researchers at Rice University allowed them to refine their process for creating laser-induced graphene. Credit: Courtesy of the Tour Group

Rice University scientists who invented laser-induced graphene (LIG) for applications like supercapacitors have now figured out a way to make the spongy graphene either superhydrophobic or superhydrophilic. Until recently, the Rice lab of James Tour made LIG only in open air, using a laser to burn part of the way through a flexible polyimide sheet to get interconnected flakes of graphene. But putting the polymer in a closed environment with various gases changed the product’s properties. Forming LIG in argon or hydrogen makes it superhydrophobic, a property highly valued for separating water from oil or de-icing surfaces...

David Newman et al. Performance of a quantum heat engine at strong reservoir coupling, Physical Review E (2017). DOI: 10.1103/PhysRevE.95.032139 

Research from The University of Manchester has thrown new light on the use of miniaturised ‘heat engines’ that could one day help power nanoscale machines like quantum computers. Heat engines are devices that turn thermal energy into a useful form known as ‘work’ which can provide power – like any other engine. Dr Ahsan Nazir wanted to see how heat engines performed at the quantum level. Heat engines at this scale could help power the miniaturised nanoscale machines of the future, such as components of quantum computers.

Dr Nazir’s research showed that heat engines were inclined to lose performance at the quantum scale due to the way such devi...