A team of researchers have created a highly stretchable touchpad that can be used to write words and play electronic games. This development could pave the way for flexible, wearable devices with numerous applications.
Superman fans often remember how the Man of Steel produced a diamond out of a coal lump by using extreme heat and pressure generated by his bare hands.
When you reach the end of a ketchup bottle, there is always some that is left stuck to the sides. Researchers from Colorado State University lab have found a solution to this issue by developing a nonstick, nontoxic coating that allows every last drop to come loose.
Two contrasting strategies have come close in the race to develop large-scale quantum computers. One strategy is based on trapping ions, while the other is based on a traditional technology. Both can now develop a basic device, which would be able to run a range of quantum software.
Michigan State University (MSU) has conducted a research study that displays how Geobacter bacteria grow as films on electrodes to generate electricity. This process is now ready for industrial applications and has been featured in the recent issue of Nature Communications.
A microneedle drug monitoring system has been developed by a team of researchers from the University of British Columbia (UBC) and the Paul Scherrer Institut (PSI) in Switzerland. This new system is capable of enhancing patient comfort and could potentially replace expensive, invasive blood draws.
Titanium that is four times harder than steel has been discovered at Rice lab.
A physicist from the University of Houston will participate in a $7.5 million collaboration to develop an innovative material with a higher conductivity than diamonds.
University of Basel chemists have succeeded in applying computer simulations to explain transient structures in proteins. The journal Angewandte Chemie features a report in which the chemists illustrate the possibility of understanding proteins’ modes of action by using computer simulations of information at the atomic level.
Spanning from swarming bees to clustering bacteria colonies, nature amazes with its ability to self organize and execute joint, dynamic behaviors. Researchers have recently discovered a method to imitate these behaviors in active materials at microscale by modifying only one parameter.
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