The Arctic - pristine natural wilderness, unmolested by human touch? Not really. While early explorers claimed they could see 200 KM mountain peaks that certainly isn't the case today. In winter months, the Arctic actually has some of the dirtiest air in the world. It turns out even those early explorers may have been romanticizing the cleanliness a bit.

Scientists know that air pollution particles from mid-latitude cities migrate to the Arctic and form an ugly haze, but a new University of Utah study finds surprising evidence that polar explorers saw the same phenomenon as early as 1870.

“The reaction from some colleagues – when we first mentioned that people had seen haze in the late 1800s – was that it was crazy,” says Tim Garrett, assistant professor of meteorology and senior author of the study. “Who would have thought the Arctic could be so polluted back then? Our instinctive reaction is to believe the world was a cleaner place 130 years ago.”

Fuel cells are commonly used in such settings as satellites, submarines or remote weather stations because they have no moving parts, do not require combustion and can run unattended for long periods of time. However, current fuel cells lose efficiency as the temperature rises and the humidity falls.

Researchers at Duke University’s Pratt School of Engineering have developed a membrane that allows fuel cells to operate at low humidity and theoretically to operate at higher temperatures. They reported their findings online in the Journal of Membrane Science.

While there are many types of fuel cells, in general they generate electricity as the result of chemical reactions between an external fuel -- most commonly hydrogen -- and an agent that reacts with it. The membrane that separates the two parts of the cell and facilitates the reaction is a key factor in determining the efficiency of the cell.

STOCKHOLM, Sweden, March 19 -- Professor John Anthony Allan from King's College London and the School of Oriental and African Studies, a pioneer of concepts key to the understanding and communication of water issues and how they are linked to agriculture, climate change, economics and politics, was named the 2008 Stockholm Water Prize Laureate.

Genetic modification holds the promise of bringing locally grown food crops to climates where farming has been traditionally difficult. Doing that means optimizing the genetics of crops in some ways without impacting them in others.

A new tool for rice genetics has made that a little bit easier. It allows rice breeders to surgically inactivate genes that confer unwanted properties.

There are many different strains of rice grown in different parts of the world and they have thrived because they are adapted to the region they grow in. In the past, introducing a gene with a beneficial modification would require years and years of breeding so that the other genes responsible for the target strains being so well adapted to their local environment were not impacted.

China’s growing participation in international trade has been one of the most prominent features of its economic reform. It is the world’s third-largest exporter, and the fastest growing exporter among members of the World Trade Organisation (WTO), which it joined in December 2001.

The secret of China’s exporting success may lie in unfair production subsidies, according to new research presented at the Royal Economics Society annual conference by a team from The University of Nottingham’s Globalisation and Economic Policy Centre (GEP).

The economists behind the research say it raises serious questions about whether China is being fair with its trading partners.

Sleep apnea is a condition characterized by temporary breathing interruptions during sleep, in which disruptions can occur dozens or even hundreds of times a night. According to the National Institutes of Health, it affects more than twelve million Americans.

Researchers at the University of Pennsylvania School of Medicine have provided a detailed look at the molecular pathways underlying sleep apnea and found that, in an animal model of sleep apnea, poorly folded proteins accumulate in one compartment of a muscle nerve cell, which, under certain conditions, tells a cell to heal itself or destroy itself.

The vision system used to process color is separate from that used to detect motion, according to a new study by researchers at New York University’s Center for Developmental Genetics and in the Department of Genetics and Neurobiology at Germany’s University of Würzburg.

The findings run counter to previous scholarship that suggested motion detection and color contrast may work in tandem.

Whether motion vision uses color contrast is a controversial issue that has been investigated in several species--from insects to humans. In human vision, it had been widely believed that color and motion were processed by parallel pathways. More recently, however, the complete segregation of motion detection and color vision came into question.

Researchers at the National Institute of Standards and Technology (NIST) have set the stage for building the “evolutionary link” between the microelectronics of today built from semiconductor compounds and future generations of devices made largely from complex organic molecules. In an upcoming paper in the Journal of the American Chemical Society, a NIST team demonstrates that a single layer of organic molecules can be assembled on the same sort of substrate used in conventional microchips.

The ability to use a silicon crystal substrate that is compatible with the industry-standard CMOS (complementary metal oxide semiconductor) manufacturing technology paves the way for hybrid CMOS-molecular device circuitry—the necessary precursor to a “beyond CMOS” totally molecular technology—to be fabricated in the near future.

Researchers at NIST and the Joint Quantum Institute (NIST/University of Maryland) have developed a new method for creating pairs of entangled photons, particles of light whose properties are interlinked in a very unusual way dictated by the rules of quantum physics. The researchers used the photons to test one of the fundamental concepts in quantum theory.

In the experiment, the researchers sent a pulse of light into both ends of a twisted loop of optical fiber. Pairs of photons of the same color traveling in either direction will, every so often, interact in a process known as “four-wave mixing,” converting into two new, entangled photons, one that is redder and the other that is bluer than the originals.