via ORNL
An ultra-high-resolution technique used for the first time to study polymer fibers that trap uranium in seawater may cause researchers to rethink the best methods to harvest this potential fuel for nuclear reactors.
The work of a team led by Carter Abney, a Wigner Fellow at the Department of Energy’s Oak Ridge National Laboratory, shows that the polymeric adsorbent materials that bind uranium behave nothing like scientists had believed. The results, gained through collaboration with the University of Chicago and detailed in a paper published in Energy & Environmental Science, highlight data made possible with X-ray Absorption Fine Structure spectroscopy performed at the Advanced Photon Source. The APS is a DOE Office of Science User Facility at Argonne National Laboratory.
“Despite the low concentration of uranium and the presence of many other metals extracted from seawater, we were able to investigate the local atomic environment around uranium and better understand how it is bound by the polymer fibers,” Abney said.
Surprisingly, the spectrum for the seawater-contacted polymer fibers was distinctly different from what was expected based on small molecule and computational investigations. Researchers concluded that for this system the approach of studying small molecule structures and assuming that they accurately represent what happens in a bulk material simply doesn’t work.
It is necessary to consider large-scale behavior to obtain the complete picture, highlighting the need for developing greater computational capabilities, according to Abney.
“This challenges the long-held assumption regarding the validity of using simple molecular-scale approaches to determine how these complex adsorbents bind metals,” Abney said. “Rather than interacting with just one amidoxime, we determined multiple amidoximes would have to cooperate to bind each uranium molecule and that a second metal that isn’t uranium also participates in forming this binding site.”
An amidoxime is the chemical group attached to the polymer fiber responsible for binding uranium.
Abney and colleagues plan to use this knowledge to design adsorbents that can harness the vast reserves of uranium dissolved in seawater. The payoff promises to be significant.
“Nuclear power production is anticipated to increase with a growing global population, but estimates predict only 100 years of uranium reserves in terrestrial ores,” Abney said. “There is approximately 1,000 times that amount dissolved in the ocean, which would meet global demands for the foreseeable future.”
Read more: ORNL technique could set new course for extracting uranium from seawater
The Latest on: Extracting uranium from seawater
via Google News
The Latest on: Extracting uranium from seawater
- A New Ultra-Adsorbent Material Can Suck Up 20 Times More Uranium Than Rival Methodson November 30, 2021 at 7:04 am
According to the Nuclear Energy Agency, it's estimated that there are at least four billion tons of uranium in the oceans, which corresponds to about 500 times the amount of uranium known to exist in ...
- Using a pore structure inspired by biological fractals to collect uranium from seawateron November 30, 2021 at 6:25 am
Inspired by biological fractals, a team of researchers affiliated with multiple institutions in China has developed a new pore structure for a membrane used to separate uranium from seawater. In their ...
- An ultra-hot gas giant exoplanet orbits its star once every 16 hourson November 30, 2021 at 12:00 am
A gas giant exoplanet has been found that orbits around its star once every 16 hours, and it is being pulled towards its star faster than any other known world. TOI-2109b is a planet five times the ...
- Material inspired by blood vessels can extract uranium from seawateron November 29, 2021 at 8:00 am
The oceans are a huge untapped store of uranium, which is vital for nuclear energy, and new technology could ensure a long-lasting supply ...
- Making The Case For Nuclear Aircrafton November 19, 2021 at 4:00 pm
Nuclear reactors use the controlled splitting of uranium atoms to produce energy. This energy is transferred into water as heat. The water is kept under high pressure, which keeps it from turning ...
- The Long History Of Fast Reactors And The Promise Of A Closed Fuel Cycleon November 18, 2021 at 4:00 pm
These would replace other types of thermal plants with one that would produce no exhaust gases, no fly ash and require only occasional refueling using uranium and other fissile fuels that can be ...
- Skyharbour Partner Company Medaro Announces Plans for Upcoming Exploration at the Yurchison Uranium Projecton November 18, 2021 at 5:04 am
and the Yurchison uranium property in Northern Saskatchewan. The Company is also involved in the development and commercialization of a new process to extract lithium from spodumene concentrate ...
- Energy systemon November 8, 2021 at 4:00 pm
The ultimate back-stop technology would be extracting uranium from sea water. Through recycling and re-use you can automatically convert and extend the fuel’s life for several hundreds or thousands of ...
- Denison Announces Completion of Highly Successful Phoenix ISR Field Test Programon October 29, 2021 at 1:31 am
During the test, injection rates were matched to pumping extraction rates for balanced flow in the Test Pattern. Pumped groundwater from each of the outer wells (GWR-038, GWR-039, and GWR-041) was ...
- Uranium From Seawater Could Keep Our Lights On for 13,000 Yearson April 23, 2016 at 8:33 am
We have 4.5 billion tons of uranium in seawater. Half of that amount is enough to power nuclear plants worldwide for 6,500 years. However, unfortunately, the costs of extracting uranium from ...
via Bing News
