Can we power a light bulb with positrons?

In summary, the conversation discusses the use of anti-tungsten, anti-copper, and other anti-matter substances in a lightbulb. It is determined that anti-argon and possibly other anti-gases would also be needed, and that the lightbulb could be suspended magnetically to eliminate the need for anti-air. The conversation also delves into the possibility of using anti-matter in galaxies and how it would be difficult to detect due to the lack of x-rays.
  • #1
cragar
2,552
3
would we need anti-tungsten to do it.
 
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  • #2
Yes and anti-copper, and anti whatever gas is in the lightbulb
 
  • #3
i see
 
  • #4
And anti-glass for the bulb, and anti-air outside the anti-glass, and anti-people to look at it... :biggrin:
 
  • #5
mgb_phys said:
Yes and anti-copper, and anti whatever gas is in the lightbulb
That would be anti-argon (and a little anti-nitrogen). We'd also need anti-silicon and anti-oxygen. I suppose we could suspend it magnetically so we wouldn't need anti-air.
 
  • #6
Wouldn't the positrons annihilating with electrons (or something else for that matter) produce "light"? Probably not visible, and\or lethal, but still I'd call it a lightbulb.
 
  • #7
Back to the OP's question.
Assuming you had the tungsten filament suspended somehow so that it didn't have to touch the seal at the base of the bulb and you had a perfect vacuum in the bulb so you didn't have to worry about gas molecules hitting the anti-tugsten.

Then, yes it would work perfectly normally and you wouldn't be able to tell that the photons emitted were from anti-matter
 
  • #8
mgb_phys said:
RE positrons in our light bulbs
Assuming you had the anti-tungsten filament suspended somehow so that it didn't have to touch the seal at the base of the bulb and you had a perfect vacuum in the bulb so you didn't have to worry about gas molecules hitting the anti-tugsten filament.

Then, yes it would work perfectly normally and you wouldn't be able to tell that the photons emitted were from anti-matter

This may be slightly off the subject, but how would we determine whether some (half?) of the millions of galaxies we see through the Sloan Digital Sky Survey and other telescopes were made of antimatter? Most of the photons we see from other galaxies are from atomic transitions (e.g.; Balmer series in hydrogen) and not from beta decay, so helicity is out.
 
  • #9
Bob S said:
how would we determine whether some (half?) of the millions of galaxies we see through the Sloan Digital Sky Survey and other telescopes were made of antimatter?
You can't - the only reason to think they aren't is that you don't see the x-rays from where their anti-interstellar medium meets out interstellar medium.
 

1. Can positrons be used to power a light bulb?

Yes, positrons can be used to power a light bulb. Positrons, also known as antielectrons, have the opposite charge of electrons and can be used in a process called annihilation to produce energy. This energy can then be used to power a light bulb.

2. How does the process of annihilation work to power a light bulb?

The process of annihilation occurs when a positron collides with an electron, which results in the production of gamma rays. These gamma rays can then be converted into electricity, which can power a light bulb.

3. Are there any practical applications for using positrons to power light bulbs?

Yes, there are practical applications for using positrons to power light bulbs. This technology has been used in medical imaging, specifically in positron emission tomography (PET) scans, where the annihilation process is used to produce gamma rays for imaging purposes.

4. What are the advantages of using positrons to power light bulbs?

One advantage of using positrons to power light bulbs is that it is a clean energy source. The annihilation process does not produce any harmful byproducts, making it environmentally friendly. Additionally, positrons have a high energy density, meaning they can produce a significant amount of energy in a small space.

5. Are there any challenges or limitations to using positrons to power light bulbs?

Yes, there are some challenges and limitations to using positrons to power light bulbs. One major limitation is the difficulty in producing and controlling positrons. Positrons are not naturally occurring and must be created in a laboratory setting. Additionally, the technology and infrastructure needed to harness and convert the energy from positrons into electricity is still in development.

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