Most Popular Issues
Most Commented Issues
Gizmorama - Nanoparticles offer a boost to food crop production
0 Comments »
Gizmorama - May 4, 2016
Here's some good news for farmers. Researchers have discovered a way to use nanoparticles to increase crop production while minimizing fertilizer waste. That's astounding!
Learn about this and more interesting stories from the scientific community in today's issue.
Until Next Time,
P.S. Did you miss an issue? You can read every issue from the Gophercentral library of newsletters on our exhaustive archives page. Thousands of issues, all of your favorite publications in chronological order. You can read AND comment. Just click
*-- Nanoparticles offer a boost to food crop production --*
ST. LOUIS - Researchers at Washington University in St. Louis have found a way use nanoparticles to boost crop production while minimizing fertilizer waste.
They detailed their feat in a new paper published this week in the Journal of Agricultural and Food Chemistry.
As farmers and the agricultural industry work to meet the food demands of a growing populace, more and more phosphorous, the main ingredient in fertilizer, is being dumped into the soil. Unfortunately, crops can only absorb so much phosphorous.
The excess fertilizer gets washed away as runoff, polluting waterways and encouraging large oxygen-sucking, fish-killing algae blooms in the Gulf of Mexico, Great Lakes and waterways all over the world. What's more, the world's supply of phosphorous is finite and shrinking
"If farmers use the same amount of phosphorus as they're using now, the world's supply will be depleted in about 80 years," Ramesh Raliya, a research scientist at WUSTL, said in a news release. "Now is the time for the world to learn how to use phosphorus in a more sustainable manner."
Raliya and his colleagues created zinc oxide nanoparticles derived from a fungus that helps plant roots take-up phosphorous from the soil. Zinc interacts with three essential enzymes to convert complex phosphorous found in the soil into a simplified version that can be used by the plant.
Overworked soil loses its microflora biodiversity over time, as well the enzymes that aid phosphorous uptake. Dumping more phosphorous into the soil does little good.
When the nanoparticles were applied to the leaves of mung bean plants, however, researchers observed an 11 percent increase in phosphorous absorption and 84 percent increase in the activity of the three essential enzymes.
"When the enzyme activity increases, you don't need to apply the external phosphorus, because it's already in the soil, but not in an available form for the plant to uptake," Raliya explained. "When we apply these nanoparticles, it mobilizes the complex form of phosphorus to an available form."
Researchers hope to deploy their technology in developing countries, especially in Asia. Farmers in India and China account for nearly half of the world's agricultural phosphorus use.
*-- New graphene-based film may keep your next laptop cool --*
GOTHENBURG, Sweden - As engineers squeeze electronics into smaller packages, it becomes increasingly hard to keep them cool. Enter functionalized graphene nanoflakes.
"Essentially, we have found a golden key with which to achieve efficient heat transport in electronics and other power devices by using graphene nanoflake-based film," Johan Liu, a professor of electronics production at Sweden's Chalmers University of Technology, said in a news release. "This can open up potential uses of this kind of film in broad areas, and we are getting closer to pilot-scale production based on this discovery."
Researchers imbued the graphene-based film with functionalization molecules -- molecules that are added to material's surface to encourage various chemical and physical qualities. By adding amino-silane molecules, scientists were able to enhance the film's in-plane heat conduction.
When tested, the new film significantly lowered the temperatures measured at previously identified hotspots on an electronic chip.
"This is the first time that such systematic research has been done," said Liu. "The present work is much more extensive than previously published results from several involved partners and it covers more functionalization molecules and also more extensive direct evidence of the thermal contact resistance measurement."
Researchers, who published their findings in the journal Nature Communications, said production of the film could soon be scaled up for use in electronics manufacturing.
Missed an Issue? Visit the
Login to Add Comment
There are currently no comments, be the first to Add one below!
Copywrite © 2017 Penn LLC