Plasma and Magnetic Fields: A Perpetual Motion Conundrum?

In summary, a magnetic field can create a torus or spherically shaped container which can suspend ferromagnetic particles in a fluid. These particles will spiral around the field lines due to the magnetic force and will be repelled by a gradient in the field. If the magnetic field is pulled away, the particles will cool and settle back down to the bottom of the container.
  • #1
Fischer777
89
1
I was wondering, if plasma moves moves in the same direction as a magnetic field when placed in a magnetic field, it seems that plasma would be in a perpetual state of motion if suspended inside a torus created by ring magnets, such as a tokamak. Wouldn't this violate the laws of thermodynamics, because you would essentially be creating perpetual motion? Or am I missing something?
 
Physics news on Phys.org
  • #2
The magnets don't cause the plasma to move. The particles themselves are in motion due to thermal motion (heat). The magnetic fields merely confine and guide the plasma. If the plasma cools down too far the ions will combine with the electrons and the plasma will cease to be a plasma and turn back into a normal gas.

Particles will spiral around the magnetic field lines and will be repelled by a gradiant in the field, but other than that they magnets don't do much else.
 
  • #3
You're talking about a ferromagnetic fluid yes? It'd have to be a particle suspension that could respond to an array of different charges to follow the magnetic field. A simple non-magnetic fluid would not move much because of heat unless there was a phase change involved.
 
  • #4
Fischer777 said:
I was wondering, if plasma moves moves in the same direction as a magnetic field when placed in a magnetic field, it seems that plasma would be in a perpetual state of motion if suspended inside a torus created by ring magnets, such as a tokamak. Wouldn't this violate the laws of thermodynamics, because you would essentially be creating perpetual motion? Or am I missing something?

It's confusing terminology. Perpetual motion is perfectly OK -- the Earth more or less does this as it orbits the sun, for 9 billion years any way. Superflow is a perpertual flow and is also possible. A perpetual motion machine implies that it is producing more energy than it consumes, which is not possible. So they aren't the same thing.

In a tokomak there is a lot of energy going into the electromagnets. It can't be built in such a way as to not lose energy. Pull the plug and it will cool down.
 
  • #5
sequenced magnetic disturbance + ferromagnetic fluid +torus or spherical shaped design = fun science.
 

1. What is plasma in a magnetic field?

Plasma in a magnetic field refers to a state of matter where a gas is ionized and becomes electrically conductive in the presence of a magnetic field. It is often described as the fourth state of matter, alongside solid, liquid, and gas.

2. How is plasma affected by a magnetic field?

The behavior of plasma in a magnetic field is highly dependent on the strength and direction of the magnetic field. In general, a magnetic field can confine, guide, or shape the movement of plasma particles, leading to complex dynamics and phenomena.

3. What are some applications of plasma in a magnetic field?

Plasma in a magnetic field has a wide range of applications, including fusion energy, space propulsion, plasma processing, and particle accelerators. It is also used in various industrial and medical applications, such as plasma cutting and sterilization.

4. How is plasma in a magnetic field studied?

Scientists use various experimental and theoretical methods to study plasma in a magnetic field. This includes laboratory experiments using plasma devices, computer simulations, and theoretical models. Satellites and spacecraft also provide valuable data on plasma behavior in space.

5. What are some challenges in understanding plasma in a magnetic field?

Plasma in a magnetic field presents numerous challenges due to its complex behavior. Understanding and controlling plasma instabilities, turbulence, and heating are major research areas. Additionally, the extreme temperatures and pressures required for fusion energy also pose technical challenges in practical applications.

Similar threads

How is current induced in the plasma in a tokamak?
    • Electromagnetism
Replies
2
Views
2K
I Railgun: Significant magnetic field where projectile is?
    • Electromagnetism
Replies
8
Views
730
I Induced electric fields and induced magnetic fields confusion
    • Electromagnetism
Replies
9
Views
1K
I The vector math of relative motion of wire-loop & bar magnet
    • Electromagnetism
Replies
1
Views
1K
How do plasma particles interact with a magnetic field?
    • Electromagnetism
Replies
4
Views
2K
I Homopolar generator question: Magnetic “wake”
    • Electromagnetism
Replies
7
Views
1K
B A moving magnet in a linear electric field
    • Electromagnetism
Replies
8
Views
786
I Magnetic field as result of length contraction
    • Electromagnetism
Replies
17
Views
1K
Suspend a magnet on a pendulum above a repelling magnet
    • Electromagnetism
Replies
1
Views
2K
B Magnetic generator multiple poles. Cancel out or short circuit?
    • Electromagnetism
Replies
8
Views
983

Hot Threads

Recent Insights

Back
Top