Why We Should Shift to Nuclear Power: Benefits and Solutions

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In summary, solar and wind are good alternatives to fossil fuels, but nuclear power is not the only alternative.
  • #1
hagopbul
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oil have give us so much pain and blood .

it gives us problems in middle east,and with environment, opec, ...etc

so why we don't shift to the nuclear power just that simple (and for the nuclear wast if we have we can send it to the space)

so why not...
 
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  • #2
hagopbul said:
oil have give us so much pain and blood .

it gives us problems in middle east,and with environment, opec, ...etc

so why we don't shift to the nuclear power just that simple (and for the nuclear wast if we have we can send it to the space)

so why not...

Last Thursday, I went to a talk by a founding member of Greenpeace (and former president of Greenpeace Canada for nine years) who now promotes this.
 
  • #3
ok when?
after 10000000000 year...
 
  • #4
hagopbul said:
ok when?
after 10000000000 year...

It's the usual misunderstanding about nuclear waste.

Nuclear waste has 3 components:

- immediately most active and "final" ashes: the fission products: decay time of the order of 300-500 years

- small quantities of unwanted "minor actinides" which could be eliminated in future combustion cycles: decay time of the order of 10 000 years

- plutonium: actual "generated fuel" that is sometimes just left in the waste:
decay time of the order of 100 000 years. In countries with a fuel cycle, this is already extracted (to make MOX).

With decay time, I mean here: the time needed to be of the same (low) activity level as the original raw uranium ore that came out of the mine.

So the strictly necessary and uncompressible decay time to "background" is only of the order of a few centuries.

And now, think about this: how long does it take heavy metals in chemical waste to decay ?
 
  • #5
There is a gradual renewal of interest in nuclear energy. Clearly there needs to be an alternative to the current reliance on fossil fuels. But there are also significant technical, envirnomental and economic issues involved. Switching to nuclear is not so simple and straightforward.

Keep in mind that as the demand for nuclear energy increases, it's cost will increase as well. It takes about 5-6 years to build a single nuclear plant, and in most countries, there is a shortage of qualified trades people who are needed to build the plants.


Disposal of nuclear waste in space is not an option. It cost about $10,000/kg to put something in orbit, and more if one wants to send it far away. That's not certainly not economical with respect to nuclear waste. Then there are the safety aspects.


Nuclear energy also does not address the current transporation infrastructure which is based upon personal mobility, vis-a-vis automobiles - and buses, trucks and aircraft. A large proportion of oil-based fuel is used in transportation. Trains can use electrical power, but only a small fraction of mileage is electrified.
 
  • #6
it is always about the money right
 
  • #7
hagopbul said:
it is always about the money right
Um - yep. Eventually it comes down to a rather simple economic proposition - at least in the industrialized modern age. Of course, one could be a nomadic hunterer-gatherer.
 
  • #8
Another problem with fission is that there is a limited amount of uranium available. Apparantly the prices are already going up. Now, we are not likely to run out any time soon (the estimates seem to range betwen 50-100 years) and presumably new deposits will be found, but that does not change the fact that fission -like oil- is only a temporary solution to the worlds energy problems.

Moreover, there is no way to completely separate civilian and military use of fission; if we want to world to use more nuclear power we will have to accept that ALL (or at least most) countries will need to have nuclear power plants of their own and quite a few will have to build enrichment facilites that can -in principle- also can be used to make weapon-grade uranium. Another problem is of course that even a civilian power plant can be quite dangerous if it ends up being located in the middle of a civil war, someone is bound to figure out that a nuclear meltdown is quite an efficient method of killing a lot of people and force any surviors to leave the area.
 
  • #9
With fast reactors and reprocessed fuel we could have several thousand years.
 
  • #10
hagopbul said:
it is always about the money right
Sort of. Right now the economics are driven by the politics and in the US, anyway, the politics are not favorable. In France, the politics are favorable, so they use nuclear power almost exclusively. Put quite simply, the hippies killed nuclear power in the US in the '60s and '70s, to the severe detrement of our country. Flower power will not drive a turbine. But the economics is what is now bringing it back. Electricity is getting expensive as oil prices rise. Other countries are seeing a resurgence of the dangerous attitudes that killed nuclear power in the US. Germany, for example, is setting itself up for an economic disaster right now with it's "environmental" policy for alternate energy, which does not include nuclear power.

That huge drawback of nuclear power, the waste containment issue, was also invented by "environmentalists". It simply doesn't exist. For the short-mid term (the next hundred years or so), on-site storage plus reprocessing makes the Yucca mountain project irrelevant. For the longer term, well, if you reprocess the fuel, there is little that needs to go anywhere except a nice, safe, landfill. Anything worse can be stored in a mountan, but it only needs to be secure for a hundred years at a time. The 10,000 year lifespan engineering criteria of the Yucca project is just crack smoking, pure and simple. You cannot design a structure for that kind of longevity, even if you had to, and in this case, you don't. If our civilization deteriorates enough that we can't maintain the facility or create a new one a hundred years from now, the need for it to be secure goes away as well.

So no, on this issue, the politics is driving the money more than anything else.
 
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  • #11
f95toli said:
Another problem with fission is that there is a limited amount of uranium available. Apparantly the prices are already going up. Now, we are not likely to run out any time soon (the estimates seem to range betwen 50-100 years) and presumably new deposits will be found, but that does not change the fact that fission -like oil- is only a temporary solution to the worlds energy problems.
To expand on Kurd's statement, the 50-100 years estimate comes from so-called environmentalists who have so far succeeded in keeping reprocessing illegal in the US. Imagine - "environmentalists" who are against recycling!

I'm a little on the distrustful side, so when I see people doing such irrational things, I think that unless they are incredibly naive, there must be another motive at work. Ostensibly, though, reprocessing was outlawed (by presidential order) for nuclear proliferation reasons.
 
  • #12
True, with reproccssing it would last much longer.
However, as far as I understand the problem with reprocessing is that it requires more or less the same type of plants as are used for enrichment (it is basically isotope separation) which just brings us back to my main point about the security issues (I am not usally paranoid, but having a lot of enriched uranium floating around makes me nervous, even if it is only reactor-grade).

I am not a big fan of nuclear power, in my view it is too dangerous and too difficult to control. Imagine a world where all the exisiting fossil fuel power plants were replaced by fission reactors; from a CO2 point-of-view it would be a good thing; but the drawback is that there would be a LOT of fission reactors around; many of them in poor countries and quite a few in places that are politically unstable. Remember that the worlds energy consumption is rapidly going up.

I wouldn't really have a problem with fission as a short term solution (i.e. replacing the current generation of reactors in countries that already have nuclear power) if it wasn't for the fact that it is likely to kill off all funding to research into viable -but in the short term very expensive- alternatives such as fusion. I don't really have much faith in the political system when it comes to research funding, the only way to make sure the neccesary funds become available is if the general public and industry start fearing that we will run out of energy; only then will there be enough pressure on the politicians to invest the hundreds of billions of dollars that will be needed.
 
  • #13
f95toli said:
However, as far as I understand the problem with reprocessing is that it requires more or less the same type of plants as are used for enrichment (it is basically isotope separation)
Nope it's basically chemical - you remove the waste products that you don't want, you aren't trying to extract pure U235. The technology to enrich U has nothing to do with reactors it's more precison machining.

which just brings us back to my main point about the security issues (I am not usally paranoid, but having a lot of enriched uranium floating around makes me nervous, even if it is only reactor-grade).
Reactor fuel is a pretty useless starting point for a weapon. The same non-proliferation treaty that we keep going on about says that we (nice safe countries with nuclear weapons) are supposed to provide the uranium for them in return for them not trying to play with the stuff themselves.

but the drawback is that there would be a LOT of fission reactors around; many of them in poor countries and quite a few in places that are politically unstable. Remember that the worlds energy consumption is rapidly going up.
We don't seem to mind have high pressure gas pipelines or Methyl-cyanide plants in poor countries - presuably because an accident only effects the locals.

I wouldn't really have a problem with fission as a short term solution (i.e. replacing the current generation of reactors in countries that already have nuclear power)
So India, Pakistan, South Africa, Brazil are allowed them but Switzerland, Holland, Germany, Sweden aren't.
The only country I can think of that built nuclear power plants primarily for power rather than weapons research is Canada.

if it wasn't for the fact that it is likely to kill off all funding to research into viable -but in the short term very expensive- alternatives such as fusion.
Fusion + short term + viable - aren't often used in the same sentance.
 
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  • #14
mgb_phys said:
Nope it's basically chemical - you remove the waste products that you don't want, you aren't trying to extract pure U235. The technology to enrich U has nothing to do with reactors it's more precison machining.

I admitt I don't know much about the technology, but isn't the technology (which as you say is mainly chemical) monitored precisely because it CAN be used to extract Pu from fuel coming from commercial reactors?

Reactor fuel is a pretty useless starting point for a weapon. The same non-proliferation treaty that we keep going on about says that we (nice safe countries with nuclear weapons) are supposed to provide the uranium for them in return for them not trying to play with the stuff themselves.

Well, I think we can safely forget about providing uranium for others. I would be VERY suprised if a majority of countries in the world would accept having to get all their fuel from a minority that was sitting on all the facilties for making reactor-grade uranium. Look at the current situation with Iran, whether or not they want to enrich uranium for military use is irrelevant; the point is that they can -with some justification- claim that it is in their national interest not having to rely on someone else for their uranium even if it is for civilian reactors.

We don't seem to mind have high pressure gas pipelines or Methyl-cyanide plants in poor countries - presuably because an accident only effects the locals.
You got a point. But you are also right that it only affect the local population, a nuclear meltdown in a badly maintained power plant will affect a large area. I grew up on the east coast of Sweden and we were quite badly affected by the Chernobyl disaster (bad luck with the wind). The hunters in the are were I am from still have test the meat from time to time. And as you know Sweden is quite far from Chernobyl



Fusion + short term + viable - aren't often used in the same sentance.
[/Quote]

Short term is something like 50 years in this case.
I was at a superconductivity conference recently and went to one of the talks about the magnet system in ITER. One of the older speakers had been working on the magnet design for over 20 years and since the project is now done (the design has been finalized) he had recently started working on the next generation (DEMO).
In his talk he pointed out that a large portion of the people in the audience would be dead before DEMO goes online (even in the best case scenario); and even the youngest people in the room (PhD students) would be close to retirement.
 
  • #15
How many reactors would have to be built to replace 100% of our (USA's) consumption of oil as a power source (non auto)?
lets say with 1998 numbers:
Oil Only 36 quadrillion BTU's consumed (1 year)
A nuclear PWR plant can output at 1500MWe, which leads to a calculation of about 803 PWR plants to replace Oil alone (Not counting natural gas and coal).

Is 803 a big number? Well its about double what the WORLD has in operation at this moment.

I could only imagine how much our demands would increase during the lengthy production of these plants. But then again maybe power plants in the future will be able to output more.
 
  • #16
f95toli said:
I admitt I don't know much about the technology, but isn't the technology (which as you say is mainly chemical) monitored precisely because it CAN be used to extract Pu from fuel coming from commercial reactors?
The technology to reprocess spent fuel into MOX is the same as to extract Pu from reactors. This is the only way to get Pu, although you generally use a different reactor design if your aim is Pu rather than power - you can see this is the design of most 'civil' reactors from the 40s/50s!
The technology to enrich U235 doesn't require you to have a reactor - just very good precision machinery for centrifuges or a lot of copper for race tracks.


Well, I think we can safely forget about providing uranium for others. I would be VERY suprised if a majority of countries in the world would accept having to get all their fuel from a minority that was sitting on all the facilties for making reactor-grade uranium.
We are quite happy to get our oil/gas from countries we don't exactly trust!
The UK is building a new fleet of Trident missile subs against our tradiational cold war enemy - who will also supply 80% of our natural gas.

I grew up on the east coast of Sweden and we were quite badly affected by the Chernobyl disaster (bad luck with the wind). The hunters in the are were I am from still have test the meat from time to time. And as you know Sweden is quite far from Chernobyl
But the UK or Norway building a few dozen coal fired power stations would effect you a lot more - I don't think the lakes and forests in Sweden have recovered from the UK's acid rain yet.

Actually you probably also receive more radiation from UK coal power statiosn than from Chernobyl - how dangerous this is depends on the particular isotopes and where they end up, you tend to get a lot of Thorium from coal which isn't as bad as the Ceasium from Chernobyl which concentrates in biology a lot more.
 
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  • #17
K.J.Healey said:
How many reactors would have to be built to replace 100% of our (USA's) consumption of oil as a power source (non auto)?
lets say with 1998 numbers:
Oil Only 36 quadrillion BTU's consumed (1 year)
A nuclear PWR plant can output at 1500MWe, which leads to a calculation of about 803 PWR plants to replace Oil alone (Not counting natural gas and coal).

Is 803 a big number? Well its about double what the WORLD has in operation at this moment.

I could only imagine how much our demands would increase during the lengthy production of these plants. But then again maybe power plants in the future will be able to output more.
The 104 operating nuclear reactors in the US supply about 20% of the electricity. Several produce less than 1 GWe. Most modern nuclear plants produce ~1.1 GWe, and the newest largest ones are aimed for ~1.5-1.6 GWe. Replacing all the oil and coal plants would require about 300-400 new nuclear plants (depending on capacity), and that would leave natural gas peaking plants for reserve.

There is always reserve generation, just in case the grid or plants experience an unplanned outage or disruption.
 
  • #18
f95toli said:
True, with reproccssing it would last much longer.
However, as far as I understand the problem with reprocessing is that it requires more or less the same type of plants as are used for enrichment (it is basically isotope separation) which just brings us back to my main point about the security issues (I am not usally paranoid, but having a lot of enriched uranium floating around makes me nervous, even if it is only reactor-grade).
Since we already have nuclear wepons, where is the proliferation issue.
I am not a big fan of nuclear power, in my view it is too dangerous and too difficult to control.
Quite frankly, that's just naive. Despite what the naysayers would have you believe, the only nuclear power related accident to kill anyone was Chernobyl and more people die in coal mines every year than died as a result of Chernobyl. And that is to say nothing about the hundreds of thousands coal power has killed with pollution.

For control, which is more under control, a plume of toxic smoke dumped directly into the atmosphere or a rod of fuel that never leaves its concrete and steel bunker?
Imagine a world where all the exisiting fossil fuel power plants were replaced by fission reactors; from a CO2 point-of-view it would be a good thing; but the drawback is that there would be a LOT of fission reactors around; many of them in poor countries and quite a few in places that are politically unstable. Remember that the worlds energy consumption is rapidly going up.
This is true, but I think you underestimate where the demand for power is. Part of what makes a country stable is also what makes a country need power. So if a country like the Sudan doesn't get a nuclear reactor, that doesn't have a major impact on the global energy outlook. Virtually all of the power is used by a handful of big countries. And since nuclear technology is expensive, there isn't much to fear about a country like the Sudan getting nuclear power - they won't because they don't have the money to.
I wouldn't really have a problem with fission as a short term solution (i.e. replacing the current generation of reactors in countries that already have nuclear power) if it wasn't for the fact that it is likely to kill off all funding to research into viable -but in the short term very expensive- alternatives such as fusion.
Well, it would be ok with me if fission took the lions' share of the funding for a while. Research into fission was essentially halted in the 70s and 80s and as a result, the bang-for-buck potential for fission research is much higher than for fusion.
I don't really have much faith in the political system when it comes to research funding, the only way to make sure the neccesary funds become available is if the general public and industry start fearing that we will run out of energy; only then will there be enough pressure on the politicians to invest the hundreds of billions of dollars that will be needed.
We are running out of energy and that's why nuclear power is now making a comeback. Fundamentally, the massive blackouts and rolling brownouts we've seen in the past few years are a result of insufficient generation and transmission capacity.

It is pathetic, really - part of what makes a developed country a developed country is a reliable power grid. And on that measure, we're going backwards. But it is fitting that the hippies are paying the most for their asinine beliefs, with high costs and unreliable power being the worst in the west. It warms my heart.
 
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  • #19
K.J.Healey said:
How many reactors would have to be built to replace 100% of our (USA's) consumption of oil as a power source (non auto)?
lets say with 1998 numbers:
Oil Only 36 quadrillion BTU's consumed (1 year)
A nuclear PWR plant can output at 1500MWe, which leads to a calculation of about 803 PWR plants to replace Oil alone (Not counting natural gas and coal).

Is 803 a big number? Well its about double what the WORLD has in operation at this moment.

I could only imagine how much our demands would increase during the lengthy production of these plants. But then again maybe power plants in the future will be able to output more.
Most reactors are on the order of 1000 megawatts and most plants have 2-4 reactors, but otherwise, yeah, you're on about the right order of magnitude. [edit - bad stats] Here's where we get our power:
Coal: 2,013,179 GWh
Nuclear: 781,986 GWh
Gas: 757,974 GWh
Hydro: 263,029 GWh
Fuel Oil: 122,522 GWh
Biomass: 63,856 GWh
http://www.eei.org/industry_issues/industry_overview_and_statistics/industry_statistics#capacity
 
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  • #20
K.J.Healey said:
How many reactors would have to be built to replace 100% of our (USA's) consumption of oil as a power source (non auto)?

To give you an idea, France went "totally nuclear" in about 20 years time: they started mid-seventies, and they were about finished mid nineties. They now have about 58 PWR running, and that's good for about 80% of the total electricity consumption (and a lot of spare power to help the Germans when they have problems :rofl: ).
Now, taking that the PER CAPITA economic muscle of the US right now is certainly not less than France's was in the 80-ies, it should take the US about the same or less time to do the full conversion.
Given that in the US about ~100 reactors (most of them rather old!) generate 20% of the electricity consumption, 5 times more should do the thing, and the PER CAPITA effort - which didn't ruin France at all - shouldn't be unbearable. Of course, there might be some delay in getting the industry capable of such an output up and running.

Economically, the US has without the slightest bit of doubt the muscle to do a total nuclear conversion. Hell, your Irak war would already have bought you about 500 reactors! And the price of the reactor is about the total price: on the life time of a reactor, the fuel cost is about 5% of the total cost...

As others pointed out, there will be a shortage of fresh uranium ore in about 50-100 years, which is about exactly the time scale needed to have a large deployment of breeders, which can extract about 100 times more energy from the "waste" than has already been extracted. The technology exists already since about 50 years, btw, the very first US power reactor WAS a fast breeder. But one has to improve upon the total security, cost and reliability of these systems, and 40 years of research/devellopment is largely sufficient.

So this is about the next best thing after renewables: reuse your waste and be happy for a few 1000 years. No more geopolitical bickering to get to the ressources, you have them already in your waste bins!

In France, they want to have their first prototype fast breeder (after Superphenix, shot down by the Green boys in the 90ies) up and running beginning of the 2020ies, to be able to switch to large scale production around 2040.
 
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  • #21
The saddest day in the energy history of western Europe was when the politically subjective groups successfully killed the quick breeder at Kalkar just about at the moment that it was ready to go operational. The largest destroyment of invested capital that I know of.

Russ_Watters said:
Germany, for example, is setting itself up for an economic disaster right now with it's "environmental" policy for alternate energy, which does not include nuclear power.

Indeed; presently in Germany there is no way to look at an horizon and not see a wind turbine. Advantage: it delivers the power of 0,001 - 0,0025th nuclear power plants for ~25% of the time.

Disadvantage: It will need 3-5 years before the energy is gained back that was required to build it, maintain it and decommission it after useful life. The question is valid if it will ever return the investment done to build them. A complete network of conventional powerplants need to be available for peak consumptions during zero wind. And the switchology in the networks, due to unpredictable variable loads is an increasing nightmare for the operators. But worst of all many bird species avoid areas with them, effectively reducing the size of the biotopes.

But it makes us feel good, so who cares.
 
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  • #22
Andre said:
Indeed presently in Germany there is no way to look at an horizon and not see a wind turbine.
The horizon in Germany is to burn the coal in Poland and ship the power rather than ship the coal and burn it in Germany - this has the advantage that the pollution mainly goes east.
Add in Russian natural gas for peak load and you're set - so long as you can build luxury cars to sell to the Russians as fast as you can use their natural gas ;-)
 

1. What are the benefits of shifting to nuclear power?

Shifting to nuclear power has several benefits, including:

  • Reduced carbon emissions: Nuclear power plants do not emit carbon dioxide or other greenhouse gases, making it a cleaner energy source compared to fossil fuels.
  • Reliable and consistent power: Nuclear power plants operate 24/7 and have a high capacity factor, providing a stable and consistent source of electricity.
  • Lower electricity costs: The cost of nuclear power is generally lower than other sources of energy, such as coal and natural gas.
  • Job creation and economic growth: Building and operating nuclear power plants creates jobs and can contribute to local and national economies.
  • Decreased dependence on foreign energy sources: Nuclear power can help reduce a country's dependence on imported energy, increasing energy security.

2. What are the potential solutions to nuclear power's waste management problem?

Nuclear power plants do produce radioactive waste, but there are several solutions to managing this waste, including:

  • Storage: Nuclear waste can be stored safely in specially designed facilities, such as dry cask storage, until a permanent disposal solution is found.
  • Reprocessing: Nuclear waste can be reprocessed to extract usable fuel, reducing the amount of waste and extending the lifespan of nuclear fuel.
  • Geologic disposal: Deep geological repositories can be used to safely store nuclear waste for thousands of years.

3. Is nuclear power safe?

Nuclear power is generally considered to be safe, but like any form of energy production, there are risks involved. However, nuclear power plants have multiple layers of safety features and protocols in place to prevent accidents and mitigate any potential risks. The nuclear industry also has strict regulations and oversight to ensure the safety of both the workers and the public.

4. What about the potential for nuclear accidents?

While nuclear accidents can and have occurred, they are rare and have become even less likely with advancements in technology and safety measures. Additionally, the consequences of a nuclear accident can be mitigated through emergency preparedness and response plans. It is also important to note that other forms of energy production, such as coal and oil, have also had significant accidents with damaging consequences.

5. How does nuclear power compare to other sources of energy?

Nuclear power is a reliable and efficient source of energy that has several advantages over other sources, such as:

  • Lower carbon emissions: As mentioned, nuclear power does not emit greenhouse gases, making it a cleaner form of energy compared to fossil fuels.
  • Higher energy output: Nuclear power plants have a high capacity factor, meaning they can produce large amounts of electricity consistently.
  • Less land use: Nuclear power plants require less land compared to other renewable energy sources, such as wind and solar.
However, it is important to consider the potential risks and costs associated with nuclear power, as well as the various energy needs and resources of different regions and countries.

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