An anonymous reader quotes a report from New Atlas: By making alterations to the plastic manufacturing process, scientists hope to produce forms of the ubiquitous material that can break down far more safely and quickly in the environment than current versions do. Researchers in China have now demonstrated a new example of this that degrades in just a week when exposed to sunlight and oxygen, which they believe could make for electronics that are easier to dispose of at the end of their lives. The new material came about when study author Liang Luo from China's Huazhong University of Science and Technology was working on an advanced type of chemical sensor, as reported by PNAS. The materials scientist was developing a novel polymer film that changed color in response to pH levels. This process was driven by the material's unique molecular structure, with the chains of monomers giving the film its deep red color, and taking it away when these bonds were broken.

Through his team's experiments, Luo found that the deep red color of the film quickly faded away and the material broke apart after several days in the sunlight. Breaking apart these bonds is a common objective in research efforts to better recycle plastics, and in doing so Luo may have inadvertently conjured up a promising, environmentally friendly version of the material. The molecular makeup of the plastic means it wouldn't be suited for use in soda bottles or shopping bags, as it is only stable as a functional material in the dark and without oxygen. But exposed to sunlight and air, it disintegrates rapidly and completely decomposes within a week, leaving no environmentally damaging microplastic fragments behind. A byproduct of the process is naturally occurring succinic acid, however, which could potentially be upcycled for commercial use in pharmaceuticals or food.

David Nield shares the findings of a new study via ScienceAlert: Researchers tasked 42 adult volunteers with learning the Arabic alphabet from scratch: some through writing it out on paper, some through typing it out on a keyboard, and some through watching and responding to video instructions. Those in the handwriting group not only learned the unfamiliar letters more quickly, but they were also better able to apply their new knowledge in other areas -- by using the letters to make new words and to recognize words they hadn't seen before, for example. While writing, typing, and visual learning were effective at teaching participants to recognize Arabic letters -- learners made very few mistakes after six exercise sessions -- on average, the writing group needed fewer sessions to get to a good standard.

Researchers then tested the groups to see how the learning could be generalized. In every follow-up test, using skills they hadn't been trained on, the writing group performed the best: naming letters, writing letters, spelling words, and reading words. The research shows that the benefits of teaching through handwriting go beyond better penmanship: There are also advantages in other areas of language learning. It seems as though the knowledge gets more firmly embedded through writing. The research has been published in Psychological Science.

Jupiter's moon Europa contains a voluminous ocean of liquid water under its icy crust that could potentially host extraterrestrial organisms. "But as evidence builds that Europa could be habitable under its crust, a problem remains: the intense radiation that Jupiter emits likely annihilates any signs of life, known as biosignatures, that upwell onto the moon's surface, presenting a challenge to future missions that aim to detect life with Europa landers," reports Motherboard. "Now, a team of researchers led by Emily Costello, a postdoctoral researcher at the Hawaii Institute of Geophysics and Planetology, have shed new light on this obstacle by examining the role of "impact gardening" in the search for life on Europa." From the report: Impact gardening occurs when rocks collide with a planetary body without an atmosphere, causing a mechanical churn that continually exposes new layers of the surface, known as the "gardened zone," to all the erosive effects of space, according to a study published on Monday in Nature Astronomy. "Knowing the depth of the gardened zone is critical for the exploration of Europa as a potentially habitable world," the researchers added. "We will need to sample material below the gardened zone if we wish to discover biomolecules that have never been exposed to hazardous radiation at the surface."

Of course, that raises the question: just how deep is Europa's gardened zone? To provide an answer, the team produced the first comprehensive models of impact gardening on Europa, with the help of Moon rocks returned from the Apollo program that also show a distinct gardened zone. This approach yielded good news and bad news. The bad news is that the models suggest that impact gardening exposes the top 30 centimeters (12 inches) of Europa's global surface to radiation, on average. Contrary to previous studies that proposed the possible presence of juicy biosignatures only a few centimeters under the moon's surface, the new study finds that signs of life would be embedded much deeper in the ice.

That said, the good news is that pristine material from Europa's ocean could be sampled at shallower depths in rare circumstances, such as in the fallout of recent landslides or fresh meteorite impacts. These natural processes can excavate layers of ice from below the gardened zone and position them within centimeters of the surface. Looking for recent examples of such disturbances could reveal samples that have not experienced the damaging long-term effects of radiation yet. Fortunately, scientists will soon benefit from close-up observations of Europa from ESA's Jupiter Icy Worlds Explorer (JUICE) and NASA's Europa Clipper, both scheduled to launch in the 2020s. These spacecraft will conduct intimate flybys of Europa, and they may be able to spot regions with freshly excavated material on the surface that would be prime destinations for future lander missions.