The infamous elephant’s foot
So. When I was in my junior year of college, the dorm I lived in was built more like a high occupancy apartment rather than a college dorm room, it had a living room and a kitchenette. No built-in stove but we were allowed to have a hot plate, so I went to K-Mart and bought a double burner one.
For some reason, one of my roommates had a cereal bowl that was in the shape of a saucepan. It was made of plastic, but it was black and had a handle. One day I walk into the apartment to an ungodly chemical smell and exactly the image above.
Probably the plastic “pan” was a children’s toy that made its way into an alternate use. I probably still have a few lying around from the toddler days.
This was bigger than most children’s toy pans I’ve seen; it could probably have held a quart of water. It was used as a cereal bowl at least once.
Yup meltdowns happen sometimes. AND there’s the century-long legacy of radioactive waste!
Oh joy, I get to bust out these bad boys again! https://www.youtube.com/watch?v=4aUODXeAM-k https://www.youtube.com/watch?v=lhHHbgIy9jU
There’s also that one guy who touched the hot part and is now using that tiny blister to conduct a decades-long smear campaign against the kinds of pots used at Three Mile Island.
kyle hill is interesting to me because when he is making videos about nuclear it is either the most terrifying nuclear horror story yet or facts and statistics about how safe nuclear is. I personally believe nuclear to be a super safe and efficient way to create energy, its just something I noticed. Makes me think about how common coal accidents are and how little they are covered compared to something supposedly scary like nuclear.
Nuclear has the same problem as aviation, by average it’s many many times safer than most alternatives, but any time something goes wrong it has a high chance of going extremely wrong and making an international scene. So it’s generally safer but every accident makes world news.
I agree. We should deal with nuclear waste in the same way we handle the waste from other fossil fuels: by spreading it over the entire planet in a thin, even coating so that everyone is equally affected!
Back in middle school, our science teacher decided to make the class do a debate about different types of energy sources in order to learn about their advantages and disadvantages. I was on the pro-nuclear team, and we were wracking our brains trying to come up with a rebuttal to “but what about the waste?” until some madlad basically came up with this great argument:
We can just dump all of the nuclear waste on Belgium. It will take a really long time before it fills up, and nobody cares about Belgium anyway
The anti-nuclear team had no good response, and we actually got a point for that argument because we looked up the relevant statistics (nuclear waste output, belgium surface area, etc.) and calculated exactly how long it would take to turn belgium into a radioactive wasteland.
There’s a really simple answer to the waste problem though. And it’s super, blatantly obvious.
All nuclear material is basically ground up rocks that we dug out of a hole and then filtered the spicy bits out of. So grind it back up, pour it into concrete and stuff it back down the same hole it came from. Of course, you can’t legally do that, but that’s only because we have a ton of rules what constitutes safe disposal, etc. Recreating the original conditions basically meant you’re (re)creating something unsafe, but we do that in a LOT of places.
EDIT: For example there are regions in Belgium and the Netherlands where there is so much naturally occuring arsenic in the ground, that if you scoop a bucket full of dirt, walk 50 meters across the provincial border and put pour it out, you’re comitting (at least) three different crimes. That’s legally valid, after all, the bucket contains polluted material, but practically nonsense since you literally just picked it up, and it’s been like that long before people ever got there.
fair argument
I want to add something to it:
First of all, a lot of that uranium seems to have been there and slowly decaying for a long time. I think, what we humans did was to “wake it up” and turn it into some more violently-reacting other elements, for the sake that we get the energy out of it at an acceptable pace. Now, though, it’s severely more dangerous than it was before.
Also, I’ve an idea about what to do with the waste: Since the waste tends to activate itself due to neutron activation, put a lot of it (but just barely not enough to make a bomb) together and it will activate itself to react violently at very high speeds, but just barely not fast enough to explode (make a bomb). That way, you can get a lot of heat out of it rather quickly, and are left with burned-out material (which contains less radioactive potential).
First of all, a lot of that uranium seems to have been there and slowly decaying for a long time. I think, what we humans did was to “wake it up” and turn it into some more violently-reacting other elements, for the sake that we get the energy out of it at an acceptable pace. Now, though, it’s severely more dangerous than it was before.
it’s weird, but it’s not “more violent” it’s just more energetic. Either through enrichment, making it more potent, which is an industry standard across the entire western world. Or through making fertile material, like uranium 238, fissile by going through the decay chain until it becomes something more spicy, like pu 239 or whatever.
The big problem is that the energy it releases is definitionally incompatible to human life. That’s the ONLY problem.
oh and btw, nuclear reactors are physically incapable of “going critical” it’s physically impossible. 90% of the concern is it breaking containment from being really fucking hot, which is notably, really hard to deal with.
Or through making fertile material, like uranium 238, fissile by going through the decay chain until it becomes something more spicy, like pu 239 or whatever.
Yeah that’s what i meant.
century-long legacy
At least millenia, might be epochs (million years) …
Though if Chernobyl is any indication in a few decades nature works its way around it.
The dangerous radiation disappears much much sooner then that. And if its millions of years, the local life would adapt, more then it already has. Interesting related info: https://en.m.wikipedia.org/wiki/Radiotrophic_fungus
Interesting link, thanks. Also, radiotrophic fungus is speculation at this point and has never been found in nature.
How’d you get a photo of my stove top from tonight?
And that pot looks iron!
We’ve had this discussion here on lemmy a few days ago: practically all electricity generation is by making turbines spin.
Hydropower means river makes turbine spin. Wind power means wind makes turbine spin. Coal/gas power means combustion makes turbine spin. Nuclear means hot steam makes turbine spin.
However, that doesn’t mean that all electricity sources are spinny things.
- solar cells have no mechanically moving parts
- batteries utilize chemical energy directly
solar cells have no mechanically moving parts
ironically, large grid tie systems are starting to “emulate” the spinning mass behavior of turbine generators, since there’s an exponential failure issue waiting to crop up if you aren’t careful, as texas has already learned, a very significant part of your solar generation can just, go offline, if it decides grid conditions aren’t suitable, which can lead to LARGE drops in power production and frequency, which is likely to kill even more generation.
So the solution is to make it emulate the physical mass tied to a turbine, or at least, more generously provide power in fault like conditions, to prevent this sort of exponential breakdown of the grid. You could of course, use a large spinning flywheel to regulate grid frequency, as is being used in a few places right now. I’m not sure how popular that is, outside of wind energy. It’s likely to get more popular though.
weird little side tangent, but the frequency of electricity on the grid is essentially directly tied to the rotational speed of all turbines currently on the grid, meaning there is a very large inertia in the grid frequency, it’s weird to think about, but makes perfect sense, and it provides for an interesting problem to solve at large scales like this.
Batteries are really fucking cool btw, the fact that you can just chemically store electricity, and then use it, is really fucking crazy. The fact that it’s the most accessible technology is also insane to me. But maybe it’s just the adoption being the way it is.
Also, solar trackers are a big deal for large farms when you start to scale above residential. Those trackers physically moving the panels to optimize generation are moving pieces.
this is sort of true, it depends on the array, but from what i understand, unless you’re doing an experimental array, it’s most common to just use fixed axis mounted panels, it’s much cheaper and more cost effective that way. Ideally you would use a tracking array, which is better, but more complicated, and requires significantly more maintenance and investment. Single axis tracking arrays might be a clever solution to this problem though.
Regardless, it’s not relevant to the grid inertia problem at hand.
I dont think this is true.
I think people underestimate the value of intertia in power generation. I liken it to the way capacitors regulate voltage changes or coilovers absorb bumps and vibrations.
The inertia of the generators connected to the grid helps stabilize frequency changes caused by blackouts, power plant issues, etc. by resisting and thereby slowing down frequency decline. It buys time for grid operators to find a way to balance loads in a way that doesn’t weaken or disable the grid as a whole.
Here’s a great NREL report explaining how this all works, and what other systems we use to stabilize grid frequency.
I think people underestimate the value of intertia in power generation. I liken it to the way capacitors regulate voltage changes or coilovers absorb bumps and vibrations.
the best way to think about it is a literal flywheel, because that’s what this is, just at a grid scale, and directly tied to the frequency.
The inertia of the generators connected to the grid helps stabilize frequency changes caused by blackouts, power plant issues, etc. by resisting and thereby slowing down frequency decline. It buys time for grid operators to find a way to balance loads in a way that doesn’t weaken or disable the grid as a whole.
TLDR it moves the “OH SHIT OH FUCK” window from about < 1ms worth of time in the worst cases, to the much more manageable, seconds window.
It’s a potential challenge with moving to renewables, but not a significant one, i think. This is also a big advantage to having sources based on thermal generation, like nuclear.
That’s just another way to turn heat into electricity. Those thermocouples could also be used on a campfire.
You think that’s hot shit: https://www.sciencedirect.com/science/article/abs/pii/S2468606921000538
In theory, if you made it small enough, you could make a gamma rectenna. Considering gamma rays are often smaller than an atom, you’d have to make the antenna out of something other than atoms though. Good luck.
that’s just a modified Peltier device :)
This exists, but it’s generally only used in spacecraft.
Most terrestrial uses of RITEGs have resulted in tragedy.
Humans only have one good way to turn hot into lightning.
Spicy rocks make water hot.
Water is last year’s news. Helium is the new water now.
Hot salt is where it’s at
Are there any molten salt reactor designs that do not use water as a coolant?
Molten salt reactors use salt as the coolant
Maybe the primary coolant but all the designs i’ve seen so far use water for the secondary coolant / working fluid.
i mean… This is how most electricity production works.
Hydro, solar, wind…
hydro works in the exact same way, just with water instead of steam, solar works using PV technology, so it’s fairly novel.
And wind is basically the same thing, just using the air, instead of steam.
It’s all mechanically the same at the end of the day, excluding solar. The primary difference is that we don’t burn fuel for heat to make steam, we use potential, or kinetic energy from our environment instead.
Also to be clear, if we’re being pedantic and nitpicky, when i say most i mean percent of production. The vast majority of production globally is through coal, oil, and natural gas. All using thermal processes. And some nuclear, though not as much as solar/wind though.
If it hasn’t been already said: the issue is public perception. If you ask any American in the street what they relate to nuclear power the majority will tell you: Chorynobyl. Even though anyone that’s looked up anything knows that technology is leaps ahead of that disaster, that’s the fear mongering that everyone jumps to.
fission is bad for us
“sHoW yOUr WoRK!”
https://en.wikipedia.org/wiki/Fukushima_nuclear_accident
https://en.wikipedia.org/wiki/Runit_Island#Runit_Dome
https://en.wikipedia.org/wiki/Hanford_Site
https://en.wikipedia.org/wiki/Three_Mile_Island_accident
https://en.wikipedia.org/wiki/Chernobyl_disaster
https://en.wikipedia.org/wiki/List_of_nuclear_power_accidents_by_country
The first light bulbs ever lit by electricity generated by nuclear power at EBR-1 at Argonne National Laboratory-West, 20 December 1951.
That is a lot of “accidents” for an energy source less than one 80 years old. We only have so many places to store the waste. And the accidents.
Yeah, but keep in mind that nuclear waste has some time left to do damage. It’s not like a hydro plant is going to come back and haunt you in a 100 years from now. That’s what worries me with nuclear, aside from the fact that it’s too slow to build to be a solution to the climate crisis.
Solar, wind and hydro should be top priority in my opinion.
Edit: Want to add energy storage to top prio as well, as that is needed to balance the grid.
It’s not like a hydro plant is going to come back and haunt you in a 100 years from now.
the ecological impact of it, probably will. But that depends on whether you consider altering the ecological environment a “bad” thing or not.
That is a good point, it probably will, and I do consider it bad.
there is actually a significant history with hydropower, back when it was growing as fast as it could. We discovered that it had significant ecological impacts, in particular on things like salmon migration here in the US, so now we have to seed rivers, and have done that since we’ve built most of those plants.
There’s a reason it’s fallen out of favor. Although pumped hydro i think is uniquely equipped since it’s not nearly as disruptive as building a massive dam in a huge river.
Oxygen is bad for us, but it’s a lot better than the alternative.
fukushima was entirely a skill issue, just don’t
TMI was entirely a skill issue, and didn’t even release any significant radiation as far as we can tell. Didn’t even breakthrough the PCV, so this probably shouldn’t even be on the list.
chernobyl was a bad design, and a skill issue, plus a few other skill issues.
the runit dome was from atomic bomb testing right? Not even real nuclear power, it may have been a fission bomb, but i’m not looking into it far enough. Weird that you don’t mention nagasaki or hiroshima in that case.
the hanford site, i’m not familiar with, but im guessing this is a development plant? And probably just procedural skill issues? There have been a number of smaller accidents, most of which are due to people being stupid.
The half life of fall-out from the Hiroshima and Nagasaki bombs was a couple of decades.
The half life of nuclear waste from powerplants is anywhere from thousands of years to millions of years, depending on the mix of isotopes.
anywhere from thousands of years to millions of years
only in a strictly thermal reactor environment, if you’re using a fast reactor, something like the SSR that is currently being worked on in canada, it can both burn waste, and reduce it’s lifespan to a much more reasonable length.
As always, development is the problem, if we had more energy being focused on this, we would be farther along, but such is scientific development.
Project PACER:
Don’t feed the troll. It won’t come back, it’s too expensive.
I mean, there’s barely any difference between the heating of the earth’s mantle, i.e. geothermal, to the heating by fission. We are just kind of doing the process manually on the surface of the planet where a tiny mistake will cover it in contamination.
