Scientists Built a Tiny Battery Out of Nuclear Waste That You'll Never Have to Recharge
Popular Mechanics Article: Scientists Built a Tiny Battery Out of Nuclear Waste That You'll Never Have to Recharge
Optical Materials Article: Scintillator based nuclear photovoltaic batteries for power generation at microwatts level - ScienceDirect
Nuclear energy
is a common source of electricity and is generated in power plants throughout
the world. Harnessing nuclear energy involves nuclear fission reactions.
Nuclear fission occurs through the splitting of a nuclei into two or more
smaller nuclei, which releases energy. This can trigger a chain reaction in
which extra neutrons collide with other unstable nuclei, breaking into more
nuclei and generating more energy. Uranium is the most commonly used element in
power plants. Uranium isotopes are contained within fuel rods, which are packed
into a reactor core. The core is cooled with water to control the rate of
nuclear fission and generate steam to spin a turbine, which generates usable
energy.
Nuclear energy
accounts for around 10% of the energy consumed worldwide. As climate change progresses
and the demand for clean energy increases, that number is expected to rise in the
coming years. While nuclear energy doesn’t generate greenhouse gases, it does
generate nuclear waste from the reactions that occur within the reactor
core. Nuclear waste has residual energy and is kept in fuel cooling pools for
around five years, then moved to casks which are commonly left on site of the
power plant. Large underground storage sites are used for permanent storage of radioactive
material.
Scientists at
Ohio State University found a way to harness the residual energy of nuclear
waste and use it in batteries. Researchers used scintillator crystals, which
are materials that scintillate, or luminesce, when hit with ionizing radiation.
They paired the scintillating crystals with solar cells that can convert the
radiation into usable energy. They tested the batteries using several different
kinds of radioactive waste, including cesium-137 and cobalt-60. The cesium
isotope generated only a small amount of energy on the nanowatt scale. However, the cobalt generated
enough energy to reach the microwatt scale. They also found that using scintillator
crystals with greater volumes and surface areas generated larger power outputs.
While a relatively small amount of energy was produced in initial experiments,
the success of the batteries shows that the technology may be able to advance
in the future and eventually generate larger amounts of energy.
The Popular
Mechanics Article on the topic discussed the importance of the discovery and
some brief background on nuclear energy. It didn’t go into too much detail
about the actual design of the batteries and wasn’t very descriptive on what a
scintillator is or how it interacts with radiation. However, the article did do
a good job explaining why the batteries are important. They explained that the
batteries could be used in exploration of the deep sea or deep space, where
nuclear systems may already be used for energy. They highlighted another interesting
study done that utilized carbon-14 isotopes from graphite blocks as energy in
batteries.
The peer reviewed
article published in Optical Materials goes into much greater detail about the
mechanism of the nuclear waste batteries. They explain that the scintillator
converts radiation into visible light, an important detail that was unclear in
the Popular Mechanics article. They also went into detail about the types of
scintillators used, with a very helpful table comparing density, light yield,
wavelength of light emitted, and radiation hardness. They found that a Gadolinium
Aluminum Gallium Garnet (GAGG) were the most effective scintillators, and that the
cobalt isotope generated the largest amount of energy. The article was very thorough
in explaining the experimental setup, something which was not done at all in
the Popular Mechanics Article.
Overall, I would
rate the Popular Mechanics Article a 7/10. They did a good job of making the topic
understandable, but lacked certain details that would help further understanding
regarding the scintillators. It was unclear what a scintillator was and why it
was used in the experiment. However, they did do a good job explaining the
importance of the study and gave a good general background on nuclear waste itself.
I think that both articles could have benefited from having more detail about
the storage of nuclear waste to further the importance of finding alternative
uses for it. Overall, I think that it was an informative article to read and really
interesting to learn about, as sustainable energy solutions are becoming more important
every day. I’m looking forward to seeing how studies like these progress in the
future, and if someday a battery will be generated using the same method that can
be used for larger scale energy purposes.
I think this article was very interesting especially as seeing as thought a lot of nuclear waste just sort of gets stored away and not repurposed. Does the Optical Materials article talk about why the cobalt isotope produced more energy?
ReplyDeleteHi Seth, that's a great question! The optical materials article talked about how the cobalt isotope emits more gamma rays than the cesium. Cobalt-60 decays into nickel-60 which is high energy and emits even more gamma rays. I think this causes it to be able to produce more energy than the cesium isotope when used in the batteries.
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ReplyDeleteThanks for sharing! That is a very interesting paper and cool research! I'm curious how safe it is when they develop those battery with radioactive materials? And how easy this would be controlled to produce larger amount of energy.
ReplyDeleteGreat question! Neither article went into detail about safety, but the peer reviewed article did briefly mention complications when working with large amounts of radioactive material. They didn't really explain how the problem would be solved, as I think this will be addressed when scaling up the size of the batteries in the future.
DeleteThis is a great and informative piece! I believe one of the best ways to clean our environment is by repurposing waste into useful products, as discussed in last week’s blog. This time, the concept of converting nuclear waste into batteries is truly fascinating. I was curious about the type of scintillators used in this process and the reason behind their selection
ReplyDeleteI agree, it's really cool to convert waste into more energy! They ended up testing a bunch of different kinds of scintillators, and found that ones called Gadolinium Aluminum Gallium Garnets worked best. Properties like greater surface area and volume increased the effectiveness of the scintillators because they were able to absorb more energy at a time. They also found that they had the ideal wavelength of light emitted for pairing with solar cells.
DeleteI find this posting raises some interesting ideas...my first thought on using 'radioactive waste' and 'safe' in the same idea kind of feels like an oxymoron. I found it interesting that these will be targeted to be used in hard to reach areas, whether that be controlled by climate, geographical location, or even placed inside the body to power a pacemaker for example. This makes me wonder how these will some day be manufactured and marketed as a safe and more viable alternative.
ReplyDeleteI agree, I'm very curious to see how studies like this will advance in the future. I wish both articles talked about safety a little more, as I don't think it was really addressed in either but is definitely an important issue. I imagine using some sort of protective coating on the batteries, like lead, could help contain the radiation, but I'm interested to see what they come up with!
DeleteWhoa! This is a really cool use of nuclear waste. I know that in the past, we have just left nuclear waste literally buried in the desert to decay for as long as we could leave it alone. I do know, however, that nuclear waste is usually a hodgepodge of different isotopes that have different decay rates, gamma emissions, and concentrations. Do you think that a generalized nuclear waste would be viable to use in batteries, or would further processing (and more possible waste production) be needed?
ReplyDeleteThis is a great question! I didn't really think about how they would actually process the waste to use certain isotopes and neither article mentioned it. Since the study did seem to focus more on the cobalt isotope, I wonder if this is what they would try and separate out. However, it does seem like it might be way more effective if they develop a way to use a mix of isotopes. We will have to see what they come up with in the future!
DeleteI find it very interesting to harness the residual energy of nuclear waste for use in batteries. However, I’m concerned about potential radiation risks during the processing of nuclear waste. How can these risks be avoided? Is there any regulations or safety standards are in place to prevent radiation exposure to workers and the public?
ReplyDelete