Researchers from Drexel University who discovered a versatile type of two-dimensional conductive nanomaterial, called a MXene, nearly a decade and a half ago, have now reported on a process for producing its one-dimensional cousin: the MXene nanoscroll. The group posits that these materials, which are 100 times thinner than human hair yet more conductive than their two-dimensional counterparts, could be used to improve the performance of energy storage devices, biosensors and wearable technology.
Upon the 20th anniversary of his second, and last, Olympics, College of Engineering associate professor Prawat Nagvajara, PhD, is still modest about his accomplishments as a cross-country skier and historic team of one.
After receiving evidence-based early interventions, roughly two-thirds of non-speaking kids with autism speak single words, and approximately half develop more complex language, according to a new study led by researchers at Drexel University’s A.J. Drexel Autism Institute.
The organic light-emitting diode (OLED) technology behind flexible cell phones, curved monitors, and televisions could one day be used to make on-skin sensors that show changes in temperature, blood flow, and pressure in real time. An international collaboration, led by researchers from Seoul National University in the Republic of Korea and Drexel University, has developed a flexible and stretchable OLED that could put the technology on track for this use and a range of new applications.
In a redeeming development for one of nature’s most universally denounced pests, researchers from McGill and Drexel Universities have discovered that mosquito stingers might one day be used for high-definition 3D bioprinting. Reported in the journal Science Advances, the findings demonstrated how the needle-like structure, called a proboscis, that mosquitoes use to extract blood, when repurposed as a tip for a 3D printer, can extrude lines finer than a human hair — surpassing commercially available 3D printing tips.
