Category Technology/Electronics

Illumination of a book (‘Paradise Lost,’ by John Milton) with the nanobionic light-emitting plants (two 3.5-week-old watercress plants). The book and the light-emitting watercress plants were placed in front of a reflective paper to increase the influence from the light emitting plants to the book pages. Credit: Seon-Yeong Kwak

Illumination from nanobionic plants might one day replace some electrical lighting. By embedding nanoparticles into the leaves of watercress, engineers have induced the plant to give off dim light for nearly 4 hours. They believe engineered plants will one day be bright enough to act as desk lamps or street lights. “The vision is to make a plant that will function as a desk lamp – a lamp that you don’t have to plug in...

Electricity, eel-style. Credit: Image courtesy of University of Michigan

Inspired by the electric eel, a flexible, transparent electrical device could lead to body-friendly power sources for implanted health monitors and medication dispensers, augmented-reality contact lenses and countless other applications. The soft cells are made of hydrogel and salt, and they form the first potentially biocompatible artificial electric organ that generates more than 100 volts. It produces a steady buzz of electricity at high voltage but low current, a bit like an extremely low-volume but high-pressure jet of water. It’s perhaps enough to power a small medical device like a pacemaker.

While the technology is preliminary, Michael Mayer, a professor of biophysics at the Adolphe Merkle Institute of the Uni...

Stability test of the novel MA(1-x)GuaxPbI3 perovskite material under continuous light illumination compared with the state-of-the-art MAPbI3. A schematic of the device architecture and the simulated crystalline structure is also provided.
Credit: M.K. Nazeeruddin/EPFL

Incorporating guanidinium into perovskite solar cells stabilizes their efficiency at 19% for 1,000 hours under full-sunlight testing conditions. With the power-conversion efficiency of silicon solar cells plateauing around 25%, perovskites are now ideally placed to become the market’s next generation of photovoltaics...

Illustration of the molecular structure of the graphene nanoribbons prepared by UCLA chemistry professor Yves Rubin and colleagues. Credit: Courtesy of Yves Rubin

Tiny structures could be next-generation solution for smaller electronic devices. As electronic devices have become smaller and smaller, creating tiny silicon components that fit inside them has become more challenging and more expensive. Now, UCLA chemists have developed a new method to produce nanoribbons of graphene, next-generation structures that many scientists believe will one day power electronic devices.

The nanoribbons are extremely narrow strips of graphene, the width of just a few carbon atoms...