The spectacular variety of colours and patterns that butterflies use to ward off potential predators may result from highly localised environmental conditions known as “microhabitats”, researchers have found.

Nanometric-sized water drops are everywhere - in the air as droplets or aerosols, in our bodies as medication, and in the earth, within rocks and oil fields. To understand the behavior of these drops, it is necessary to know how they interact with their hydrophobic environment. This interaction takes places at the curved droplet interface, a sub-nanometric region that surrounds the small pocket of water. Researchers from EPFL, in collaboration with the institute AMOLF in the Netherlands, were able to observe what was going on in this particular region. They discovered that molecules on the surface of the drops were much more ordered than expected. Their surprising results have been published in Nature Communications. They pave the way to a better understanding of atmospheric, biological and geological processes.

“I’m strong to the finich, ‘cause I eats me spinach!” said Popeye the Sailor Man.

While you may not gulp spinach by the can-fuls, if you love spanakopita or your go-to appetizer is spinach artichoke dip, then you’ll be excited to know that new research out of Boyce Thompson Institute (BTI) will make it even easier to improve this nutritious and delicious, leafy green.

Pointing the National Science Foundation’s Very Large Array (VLA) at a famous galaxy for the first time in two decades, a team of astronomers got a big surprise, finding that a bright new object had appeared near the galaxy’s core. The object, the scientists concluded, is either a very rare type of supernova explosion or, more likely, an outburst from a second supermassive black hole closely orbiting the galaxy’s primary, central supermassive black hole.

When scientists develop the chemical formulas for new products such as fuels and medications, they often must first create molecules that haven’t previously existed.

A basic step toward creating new molecules is selectively breaking and re-forming the chemical bonds that connect the atoms that make them up. One of the chief challenges is that the bond between carbon and hydrogen atoms — the building blocks of many molecules — is exceptionally strong, so chemists often have to resort to using rare and expensive chemicals like iridium to convert it into other, more useful types of chemical bonds. Scientists refer to this process as “functionalizing” the bonds.

Axions are particles whose hypothetical existence was introduced in 1977 by Roberto Peccei and Helen Quinn. The particles have been the talk of the town lately because their existence could largely explain so-called dark matter. In order to make a solid claim, researchers have been measuring the interaction between axions and photons. A team of international scientists from the project CERN Axion Solar Telescope (CAST) at the European research center CERN in Geneva, Switzerland, including Prof. Dr. Horst Fischer from the Institute of Physics at the University of Freiburg, have set strict limits to the probability that axions turn into photons. They have presented their findings in the latest issue of Nature Physics.

Researchers from Lund University in Sweden and from Fudan University in China have successfully designed a new structural organization using the promising solar cell material perovskite. The study shows that solar cells increase in efficiency thanks to the material’s ability to self-organise by standing on edge.

The current research study deals with perovskite, a new and promising material in the context of solar cells. However, in its regular form, the material is very sensitive to moisture. It simply dissolves in contact with water, and even normal humidity deteriorates the material within hours or minutes. Now the researchers appear to have overcome that problem.

For years, scientists have been warning of a so-called “hot spot” of accelerated sea-level rise along the northeastern U.S. coast. But accurately modeling this acceleration as well as variations in sea-level rise from one region to another has proven challenging.

Now an upcoming paper in Geophysical Research Letters offers the first comprehensive model for understanding differences in sea level rise along North America’s East Coast. That model incorporates data not just from atmospheric pressure and ocean dynamics—changing currents, rising ocean temperatures and salinity all influence sea level—but also, for the first time, ice mass change in Greenland and Antarctica. The researchers say their model supports a growing consensus that sea level rise began accelerating in 1990 and that what they found will improve estimates of future sea level rise at a local level.

NASA astronauts Peggy Whitson and Jack Fischer are preparing for an unscheduled spacewalk outside the International Space Station Tuesday, May 23. Live coverage will begin at 6:30 a.m. EDT on NASA Television and the agency’s website.

Whitson, Expedition 51 commander, and Fischer, flight engineer, will replace a critical computer relay box that failed May 20. The relay box, known as a multiplexer-demultiplexer (MDM), is one of two units that regulate the operation of radiators, solar arrays and cooling loops. They also route commands to other vital station systems.

During the research, the scientists were to answer the following questions which are currently considered to be important in the realm of radiobiology:

What are the peculiarities of low-dose gamma radiation`s effect on living creatures?

What are the differences between gamma and alpha, beta radiation in terms of their effect on living creatures?

Photobacterium phosphoreum, which is quite suitable for a comprehensive analysis of a radiation effect, was used as a test organism. In the course of the experiment, the luminous bacteria were put into an experimental capsule where they were undergoing the effect of different radiation capacity and duration under the temperatures of +5 °C, +10 °C, +20 °C.