Helium Plasma Reaction: Magnetic Field Impact

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Discussion Overview

The discussion revolves around the behavior of ionized helium plasma and air plasma in response to magnetic fields. Participants explore the differences in movement and reactions of these plasmas under varying conditions, including the influence of atomic weight and other factors affecting plasma dynamics.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested

Main Points Raised

  • One participant notes that helium's lower atomic weight may lead to a stronger response to electric and magnetic fields compared to air, suggesting this could explain the observed differences in movement.
  • Another participant questions the relationship between atomic weight and magnetic field response, arguing that weight affects gravity but may not directly influence magnetic interactions.
  • A participant discusses the importance of buoyancy and inertia in the experiment, stating that these factors could affect how the atoms respond to pressure changes and heating.
  • Suggestions are made for collecting more data under various conditions, including temperature and magnetic field strength, to better understand the observed phenomena.
  • One participant speculates on the role of dipole moments within helium atoms and how they might contribute to the observed vibrations in the plasma.
  • Concerns are raised about the experimental setup, with a participant suggesting that the energy source may not be sufficient to create plasma, raising the possibility that the observed glow could be due to fluorescence instead.
  • Another participant introduces the concept of "Townsend avalanche" to explain the ionization process and the interaction of the initial plasma with microwaves.
  • It is noted that heavier gases may respond more sluggishly to magnetic fields, which could impact the experimental results.

Areas of Agreement / Disagreement

Participants express differing views on the factors influencing plasma behavior in magnetic fields, with no consensus reached on the underlying mechanisms or the validity of the experimental setup.

Contextual Notes

The discussion highlights limitations in the experimental design, including a lack of control over variables and the need for more comprehensive data to support claims about the behavior of the plasmas.

Physicist50
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Hello everyone, I was recently creating two different types of plasma for a Science Fair, one created from ionised Helium, (although it's the party balloon stuff, and I hear there's some Oxygen in them) and the other was created from air. I was testing how the plasmas reacted to magnetic fields. Upon ionisation, both plasmas moved a little, but when the magnet was introduced, both swayed and moved much more. Interestingly enough, the Helium one jiggled frantically, noticeably more than the air one, and I was wondering why this happens.

Thanks in advance
 
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You'll want to compare notes:
https://www.physicsforums.com/showthread.php?t=767284
... meantime, I'll think about it.

Off the top of my head: helium is a lot lighter so will respond to small changes in the electric and magnetic field more strongly, as well as the pressure variations in the inflowing air.
 
Simon Bridge said:
You'll want to compare notes:
https://www.physicsforums.com/showthread.php?t=767284
... meantime, I'll think about it.

Off the top of my head: helium is a lot lighter so will respond to small changes in the electric and magnetic field more strongly, as well as the pressure variations in the inflowing air.

Thanks Simon Bridge, but I'm still not sure I understand. Why would the weight of Helium affect how it reacts to magnetic fields? Sure, it affects how it reacts to gravity differently, but to my knowledge the two phenomena are not related.
 
The atomic weight ... related to the charge on the nucleus and the number of electrons it has. This affects the ionization energy. The mass of a particle in a box affects it's specific heat capacity - i.e. how it responds to heating, where the heat energy can get used. It's quantum.

Weight also affects buoyancy - which is important to your experiment - and is related to inertia, which goes to how the atoms respond to small pressure changes like fluctuations from uneven heating in the gas, and air flow from under the container.
 
It would help to have more data collected for the plasma, and data under multiple conditions, temperature, any temperature variations on the two samples, the mass of each sample, how ionization took place, a description of the container, and the magnetic field strength and shape. I suspect the vibration was caused by the field within the plasma and how it responded to the magnetic field. We can visualize the field for a steady unidirectional magnetic field and the motion of the protons. It would interesting if more was at play, i.e. If one considers the neutron to be a proton with a captured electron, then the states of this configuration within the atom under the condition mentioned could be enlightening. So to understand what is going on, only a guess, for me, at this time; but, with more data, we could define an hypothesis. Since the entire atom was in motion, I would suspect that the polarity of the nucleus, i.e. what's happening with the trapped two electrons, causes these difficult to measure dipoles to flip. So you might have a breakthrough on measuring the effects of the dipole moment within the nucleus of helium under ... conditions.
 
@rufusgwaren: welcome to PF - nice 1st post.
I have a feeling that the setup is similar to the other thread linked in post #2.
I x-linked from there too so replies need only go in one place.

The experiment is qualitative with very little control of variables.
The suggestions about what could be achieved with more data would make a good conclusion to the summary to the experiment write-up.

I don't think a microwave oven (OP has yet to confirm the method) delivers enough energy to make a plasma though - could the glowing stuff just be normal florescence? The match adds carbon and phosphor compounds into the gas mix.
 
Last edited:
yea, i see, could just be a modal response from the microwave. Yet, needs a little bit more science.
 
Looking further - see "Townsend avalanche".
The match provides an initial plasma (flame) and the microwaves ensure the ions don't recombine quickly - instead, collisions with the gas in the glass ionizes it, and also excites it's electrons. If this is correct then the glow is a mix of regular hot gas and plasma.

So back to standard:
There are a lot of sources for fluctuations in the experiment.
Heavier gasses will respond more sluggishly.
See notes other thread.

Finally found a paper: http://pubs.acs.org/doi/abs/10.1021/ac00235a026
Seems helium is particularly good at this.
 

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