Atomic physics topics related to nuclear power?

In summary: Sorry if this is wrong part of the board to post in...I am taking a atomic-molcular physics class right now and we are suposed to hold a 25 minute presentation in 4 weeks on a hot topic in atomic-molecular physics. If possible, I would love to take this opportunity to deepen my knowledge on nuclear power. However, I am unsure of what atomic-molecular physics-related topics are currently hot and related to nuclear power. Any help would be much appreciated!
  • #1
Azael
257
1
Sorry if this is wrong part of the board to post in...

I am taking a atomic-molcular physics class right now and we are suposed to hold a 25 minute presentation in 4 weeks on a hot topic in atomic-molecular physics.

If possible Il gladly take this as a chanse to deepen my knoweledge on nuclear power:approve: But I have no clue what atomic-molecular physics related topics that are hot and related to nuclear power right now.:confused: :grumpy:

Just looking for some general ideas that I can look into, where I can search and so on. Any help would be greatly appriciated :approve:
 
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  • #2
Atomic Vapor Laser Isotopic Separation (AVLIS) or SILVA in France.

http://en.wikipedia.org/wiki/AVLIS

The US (USEC) abandoned its attempt, but recently an Australian group has apparently perfected an economic process which it licensed to GE.

http://www.globalsecurity.org/wmd/intro/u-laser.htm

http://en.wikipedia.org/wiki/Isotope_separation

Alternative Applications of Atomic Vapor Laser Isotope Separation Technology
http://www.nap.edu/catalog/9553.html

See - http://www.freepatentsonline.com/4734177.pdf - patent.
 
Last edited:
  • #3
Azael said:
Sorry if this is wrong part of the board to post in...

I am taking a atomic-molcular physics class right now and we are suposed to hold a 25 minute presentation in 4 weeks on a hot topic in atomic-molecular physics.

If possible Il gladly take this as a chanse to deepen my knoweledge on nuclear power:approve: But I have no clue what atomic-molecular physics related topics that are hot and related to nuclear power right now.:confused: :grumpy:
Atomic and molecular physics is typically NOT about nuclear power and is quite a separate field from nuclear/particle physics.

You're taking the class right now - have you been learning about nuclear physics?
 
  • #4
Gokul43201 said:
Atomic and molecular physics is typically NOT about nuclear power and is quite a separate field from nuclear/particle physics.

You're taking the class right now - have you been learning about nuclear physics?

Ohh yes you are right this class is nothing about nuclear power.
But I am sure there are atomic physics related problems in nuclear power.

The ideas I have for my presentation(we are very free to choose topic aslong as it ties into atomic physics somehow) is.

Explaining the greenhouse gases and how they trap heat on a molecular level.
Talking about creating and storing anti hydrogen atoms.
Something related to nuclear power somehow.

So now I am just investigating the last option:approve: Simply because I take every chanse I can to read more about nuclear power:wink:
 
  • #5
Astronuc said:
Atomic Vapor Laser Isotopic Separation (AVLIS) or SILVA in France.

http://en.wikipedia.org/wiki/AVLIS

The US (USEC) abandoned its attempt, but recently an Australian group has apparently perfected an economic process which it licensed to GE.

http://www.globalsecurity.org/wmd/intro/u-laser.htm

http://en.wikipedia.org/wiki/Isotope_separation

Alternative Applications of Atomic Vapor Laser Isotope Separation Technology
http://www.nap.edu/catalog/9553.html

See - http://www.freepatentsonline.com/4734177.pdf - patent.

Thanks. That sounds like a topic perfect for my presentation:tongue2:

Can this processes be used in partitioning waste products as well in any future fuel cycle?
 
  • #6
Possibly, but given the volume of waste, I don't think LIS would be practical. It is one thing to process and energy source with LIS, with the expectation that one puts in less energy than one obtains from the stored nuclear energy, and it quite another to process waste, which represents net energy consumption.

Chemical separation is the most common bulk waste treatment process, and since this is usually done in an aqueous process, the waste stream must be de-watered, dried, calcined (in the form of metal oxides), then vitrified into a solid mass (reduced surface area), and then clad (encapsulated) in a corrosion (chemical) resistant material, which then isolates the waste from the environment, which prevents transport of radionuclides from the mass fo waste.
 
  • #7
Azael said:
Can this processes be used in partitioning waste products as well in any future fuel cycle?
Azael,

As Astronuc points out; you don't need an isotopic separation processor for the waste.

AVLIS is an isotopic separation process; which you use when you want to keep
some isotopes of an element and "discard" other isotopes. When you enrich uranium;
you want to keep the U-235 for your reactor, and you want to discard a bunch of the
U-238.

In the waste stream, you usually want to discard ALL the isotopes of a given
element; you want to discard ALL the Cesium isotopes, not just the Cesium-137.

If you want to keep isotopes; for instance Plutonium; you don't want to keep just
the Plutonium-239 for the next fuel cycle, you wnat to keep the Pu-240, Pu-241,
Pu-242.. because you don't want those isotopes in the waste stream, but to "burn"
them down to fission products in the next fuel cycle.

So isotopic separation processes like AVLIS don't do the type of separation you
need to do in the waste stream; you want to chemically separate the wastes;
not isotopically separate the wastes.

Dr. Gregory Greenman
Physicist
 
  • #8
Thanks for clearing that up :)

What process is used to separate for instance plutonium from the waste and how efficient is it? Does a substantial amount of plutonium get left in the waste after extraction?
 
  • #9
Purex process is perhaps the common chemical recovery technique. It's pretty efficient. The goal is recover as much as possible leaving behind microgram quantities, but those can also be recovered.

Since Pu is a 'special nuclear material', accountability is a big deal.

http://en.wikipedia.org/wiki/PUREX
 

1. What is nuclear power and how does it work?

Nuclear power is a form of energy that is created by splitting atoms in a process called nuclear fission. This is done in a nuclear power plant, where uranium atoms are split in a controlled chain reaction, releasing energy in the form of heat. This heat is then used to create steam, which turns turbines and generates electricity.

2. What is the difference between nuclear fission and nuclear fusion?

Nuclear fission is the splitting of atoms, while nuclear fusion is the combining of atoms. In nuclear power, fission is used because it is easier to control and sustain, while fusion is still a developing technology. In fusion, atoms of hydrogen are combined to form helium, releasing a large amount of energy.

3. What are the advantages and disadvantages of nuclear power?

The main advantage of nuclear power is that it produces a large amount of energy without emitting greenhouse gases, which contribute to climate change. It is also a reliable source of energy and can operate for long periods of time. However, a major disadvantage is the potential for accidents and radioactive waste, which can have harmful effects on the environment and human health. It is also a non-renewable energy source, as the supply of uranium is limited.

4. How is nuclear waste managed and disposed of?

Nuclear waste is managed through a process called nuclear fuel cycle. This involves storing the waste in a safe and secure facility, such as a deep underground repository, until it becomes less radioactive. Another method is to reprocess the waste, which separates the usable fuel from the waste. The leftover waste is then stored in a similar manner.

5. How does nuclear power contribute to global energy production?

Nuclear power currently accounts for about 10% of global energy production. Some countries, such as France and Sweden, rely heavily on nuclear power for their energy needs, while others, like the United States, have a smaller percentage. However, nuclear power is expected to play a larger role in the future as countries look for cleaner and more reliable sources of energy.

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