David Stauth, Oregon State University News and Communication
CORVALLIS, Ore. – The impact of hatcheries on salmonids is so profound that in just one generation traits are selected that allow fish to survive and prosper in the hatchery environment, at the cost of their ability to thrive and reproduce in a wild environment.
By Steve Law, The Portland Tribune
Researchers at Oregon State University found that compounds related to iron pyrite, or “fool’s gold,” might offer cheap and promising applications in the fabrication of solar energy cells.
Nick Houtman, Oregon State University, News & Communications
CORVALLIS, Ore. — When Sam Bartlett, an Oregon State University senior in chemistry, put on his lab coat, goggles and latex gloves in the summer of 2010, he didn’t expect to wind up helping organic chemists around the world.
With guidance from Chris Beaudry, assistant professor of chemistry, he developed the most efficient and productive method yet reported for a fundamental step commonly used to synthesize new molecules.
Bartlett and Beaudry published their findings in October in the Journal of Organic Chemistry. The research has already drawn the attention of pharmaceutical scientists and has potential in fields from nanotechnology to biochemistry.
A Science Friday adviser for NPR, Lynn Dierking talks about free-choice learning opportunities outside of the classroom for children to learn science.
Listen to the NPR story here.
Oregon State University News and Communications
11-2-2011
CORVALLIS, Ore. – One of the most comprehensive analyses yet done of the ancient history of insect-borne disease concludes for the first time that malaria is not only native to the New World, but it has been present long before humans existed and has evolved through birds and monkeys.
The findings, presented in a recent issue of American Entomologist by researchers from Oregon State University, are based on the study of insect specimens preserved in amber.
The study outlines the evolution of several human diseases, including malaria, leishmaniasis and trypanosomiasis. It makes clear that these pathogens have existed for at least 100 million years, and suggests that efforts to conquer them will be an uphill battle against such formidable and adaptive foes.
Distinguished Professor Doug Keszler leads a lab that has developed new materials with novel electrical and optical properties that have created breakthroughs in transparent electrical circuits, thin panel displays and high efficiency lighting.
To watch his presentation at the Linus Pauling Science Center Launch on October 14, 2011, please click here.
David Stauth, Oregon State University News and Communication
CORVALLIS, Ore. – Researchers in Uruguay and Oregon have discovered a previously unknown type of neural cell that appears to be closely linked to the progression of amytrophic lateral sclerosis, or Lou Gehrig’s disease, and they believe it will provide an important new approach to therapies.
There is now no treatment for this disease, which causes progressive death of motor neurons, serious debility, paralysis and ultimately death within a few years.
Even a way to slow its progression would be hugely important, scientists say.
The findings were reported today in Proceedings of the National Academy of Sciences, by researchers from the Pasteur Institute of Montevideo, Clemente Estable Institute and the Linus Pauling Institute at Oregon State University.
Oregon State University News and Communications
CORVALLIS, Ore. – The College of Science at Oregon State University recently honored a number of its faculty and staff for their accomplishments over the past year.
Tevian Dray of the Department of Mathematics and Richard Nafshun of the Department of Chemistry received the Loyd Carter Award for Outstanding and Inspirational Undergraduate Teaching, the oldest award given by the college. It recognizes faculty who have distinguished themselves in teaching.
Stephen Giovannoni of the Department of Microbiology received the F.A. Gilfillan Memorial Award for Distinguished Scholarship in Science, recognizing a body of scholarly work that has made a lasting impact on its field and on OSU. It is the highest honor that the college awards to a member of its faculty, and Giovannoni will be the presenter at the F.A. Gilfillan Memorial Award Lecture in 2012.
Other awards included:
This story is available online: http://bit.ly/r5mxM6
David Stauth, Oregon State University News and Communication
CORVALLIS, Ore. – More than 60 percent of the energy produced by cars, machines, and industry around the world is lost as waste heat – an age-old problem – but researchers have found a new way to make “thermoelectric” materials for use in technology that could potentially save vast amounts of energy.
And it’s based on a device found everywhere from kitchens to dorm rooms: a microwave oven.
Chemists at Oregon State University have discovered that simple microwave energy can be used to make a very promising group of compounds called “skutterudites,” and lead to greatly improved methods of capturing wasted heat and turning it into useful electricity.
A tedious, complex and costly process to produce these materials that used to take three or four days can now be done in two minutes.
Most people are aware you’re not supposed to put metal foil into a microwave, because it will spark. But powdered metals are different, and OSU scientists are tapping into that basic phenomenon to heat materials to 1,800 degrees in just a few minutes – on purpose, and with hugely useful results.
These findings, published in Materials Research Bulletin, should speed research and ultimately provide a more commercially-useful, low-cost path to a future of thermoelectric energy.
“This is really quite fascinating,” said Mas Subramanian, the Milton Harris Professor of Materials Science at OSU. “It’s the first time we’ve ever used microwave technology to produce this class of materials.”
Thermoelectric power generation, researchers say, is a way to produce electricity from waste heat – something as basic as the hot exhaust from an automobile, or the wasted heat given off by a whirring machine. It’s been known of for decades but never really used other than in niche applications, because it’s too inefficient, costly and sometimes the materials needed are toxic. NASA has used some expensive and high-tech thermoelectric generators to produce electricity in outer space.
The problem of wasted energy is huge. A car, for instance, wastes about two-thirds of the energy it produces. Factories, machines and power plants discard enormous amounts of energy.
But the potential is also huge. A hybrid automobile that has both gasoline and electric engines, for instance, would be ideal to take advantage of thermoelectric generation to increase its efficiency. Heat that is now being wasted in the exhaust or vented by the radiator could instead be used to help power the car. Factories could become much more energy efficient, electric utilities could recapture energy from heat that’s now going up a smokestack. Minor applications might even include a wrist watch operated by body heat.
“To address this, we need materials that are low cost, non-toxic and stable, and highly efficient at converting low-grade waste heat into electricity,” Subramanian said. “In material science, that’s almost like being a glass and a metal at the same time. It just isn’t easy. Because of these obstacles almost nothing has been done commercially in large scale thermoelectric power generation.”
Skutterudites have some of the needed properties, researchers say, but historically have been slow and difficult to make. The new findings cut that production time from days to minutes, and should not only speed research on these compounds but ultimately provide a more affordable way to produce them on a mass commercial scale.
OSU researchers have created skutterudites with microwave technology with an indium cobalt antimonite compound, and believe others are possible. They are continuing research, and believe that ultimately a range of different compounds may be needed for different applications of thermoelectric generation.
Collaborators on this study included Krishnendu Biswas, a post-doctoral researcher, and Sean Muir, a doctoral candidate, both in the OSU Department of Chemistry. The work has been supported by both the National Science Foundation and U.S. Department of Energy.
“We were surprised this worked so well,” Subramanian said. “Right now large-scale thermoelectric generation of electricity is just a good idea that we couldn’t make work. In the future it could be huge.”
-30-
Editor’s Note: Graphic images are available online to illustrate this story.
A microwave oven creating these new materials: http://www.flickr.com/photos/oregonstateuniversity/6150691793/in/photostream
Heat lost by various industrial activities: http://www.flickr.com/photos/oregonstateuniversity/6152696629/in/photostream
About the OSU College of Science: As one of the largest academic units at OSU, the College of Science has 14 departments and programs, 13 pre-professional programs, and provides the basic science courses essential to the education of every OSU student. Its faculty are international leaders in scientific research.
David Stauth, Oregon State University News and Communication
CORVALLIS, Ore. – Researchers at Oregon State University have shown for the first time that loss of biodiversity may be contributing to a fungal infection that is killing amphibians around the world – a finding that provides more evidence for why biodiversity is important to many ecosystems.
The research, being published this week in Proceedings of the National Academy of Sciences, used laboratory studies of amphibians to show that increased species richness decreased both the prevalence and severity of infection caused by the deadly chytrid fungus, Batrachochytrium dendrobatidis.
| M | T | W | T | F | S | S |
|---|---|---|---|---|---|---|
| 1 | 2 | 3 | 4 | 5 | 6 | 7 |
| 8 | 9 | 10 | 11 | 12 | 13 | 14 |
| 15 | 16 | 17 | 18 | 19 | 20 | 21 |
| 22 | 23 | 24 | 25 | 26 | 27 | 28 |
| 29 | 30 | 31 | ||||
