A type of plastic that exhibits metallic and semi-conductor-like properties will be described in an inaugural doctoral lecture at the University of Leicester on Wednesday June 4th(*).

In his lecture, Dr. M. A. Mohamoud will discuss a novel class of materials called “conducting polymers.” Conducting polymers are smart materials that can mimic biological systems and can be used as components of artificial nerves, electronic noses/tongues, drug-release-and-delivering systems, and artificial muscles.

They can also be used as energy storage devices in battery technology, electrochromic display devices (in smart window technology and light emitting diodes), and biological sensor technology.

In a paper recently published in Cortex, Jan Lonnemann (RWTH Aachen University, Germany) and colleagues report that many children at the age of 8-9 years seem to represent numbers spatially. Interestingly, boys using this kind of representation tended to have better calculation abilities, while girls who represent numbers spatially tended to show poorer calculation abilities.

The authors assume that these differences may be due to gender-specific thinking styles: for boys, who may prefer visual-spatial thinking styles, it seems to be helpful to represent numbers spatially when being confronted with calculation problems, whereas for girls preferring verbal thinking styles it may be even detrimental.

Evidence for a connection between number and space processing comes from behavioral, patient, and brain imaging data, but only a few studies have addressed this issue in children.

With the Large Hadron Collider gearing up for its first test run this summer, physicists hope to discover the last missing particle predicted by the Electroweak theory, the Higgs boson.  Wrapped up in its own big theory, the Higgs Mechanism or Higgs Field, it supposedly confers mass or absolute weight on some paricles or collections of them like atoms and planets.  The Higgs Field is a must, otherwise the Electroweak theory falls flat, insisting that all particles are massless, that matter doesn't exist.

The LHC has been sold to politicians and the public as the experiment that will find the Higgs, though in fact the LHC, no ordinary atom smasher, aims to produce it with colossal energies applied to protons, lead ions later, collided together in a mini Big Bang.  The disaster scenarios also start here.

The Antennae Galaxies, located in the constellation of Corvus (the Crow), are among the closest known merging galaxies. The two galaxies, also known as NGC 4038 and NGC 4039, began interacting a few hundred million years ago, creating one of the most impressive sights in the night sky. They are considered by scientists as the archetypal merging galaxy system and are used as a standard against which to validate theories about galaxy evolution.

Scientists using Hubble’s Advanced Camera for Surveys and Wide Field Planetary Camera 2 to observe individual stars spawned by the colossal cosmic collision in the Antennae Galaxies have reached a surprising conclusion - the Antennae are much closer than previously believed, 45 million light-years instead of the previous best estimate of 65 million light-years.

Designer labels aren't just cool to pretentious New York women - they're also the dream of nuclear physicists.

Designer isotopes, the relatively new power scientists have to make specific rare isotopes to solve scientific problems and open doors to new technologies, will compete with nanotechnology for big breakthroughs, according to Bradley Sherrill, a University Distinguished Professor of physics and associate director for research at the National Superconducting Cyclotron Laboratory at Michigan State University.

Isotopes are the different versions of an element. Their nuclei have different numbers of neutrons, and thus give them different properties. Rare isotopes don’t always exist in nature – they must be coaxed out with high-energy collisions created by special machines, like those in MSU’s Coupled Cyclotron facility. As technology advances, newer equipment is needed.

A team of Dutch and German astronomers have discovered part of the missing matter in the Universe using the European X-ray satellite XMM-Newton. They observed a filament of hot gas connecting two clusters of galaxies. This tenuous hot gas could be part of the missing “baryonic” matter.

The existence of this hot gas (with a temperature of 100 000 - 10 000 000 degrees), known as a warm-hot intergalactic medium, was predicted 10 years ago as a possible source for the missing dark matter. Gas at such high temperature and low density is very difficult to detect and many attempts have failed in past years.

The team observed a pair of clusters of galaxies (Abell 222 and Abell 223) using the European X-ray satellite XMM-Newton. Their observations (see Fig. 1) clearly show a bridge connecting both clusters. The gas they observed there is probably the hottest and densest part of the diffuse gas in the cosmic web, which would be part of the missing “baryonic” dark matter.

A group of researchers writing in Geophysical Research Letters have a new theory about Mercury’s mysterious magnetic field - iron “snow” inside the planet that forms and falls toward the center, much like snowflakes form in Earth’s atmosphere and fall to the ground.

Mercury is the closest planet to the sun and the only other terrestrial planet that possesses a global magnetic field. Discovered in the 1970s by NASA’s Mariner 10 spacecraft, Mercury’s magnetic field is about 100 times weaker than Earth’s. Most models cannot account for such a weak magnetic field.

Made mostly of iron, Mercury’s core is also thought to contain sulfur, which lowers the melting point of iron and plays an important role in producing the planet’s magnetic field.