Speed of electric spark, arc and conductive ionized gas

AI Thread Summary
Sparks and arcs consist of charged particles, primarily electrons, which do not travel at near light speed; they typically move at a few percent of the speed of light. The speed of these charged particles is influenced by the device's design, including the separation distance of charged plates and the potential difference. In devices like thyratrons, ionized gas molecules facilitate electricity conduction, but the actual movement of these molecules is not necessary for charge transfer. Lightning bolts, for example, can travel over 100,000 miles per hour, showcasing the speed of electrical discharges in the atmosphere. The flow of current in wires approaches the speed of light, but factors in a vacuum may slow electron movement.
AlSo
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Dear colleagues,

If an arc or a spark traveling in vacuum is actually the electrons jumping across vacuum, do they travel at near light speed?

From another point of view, devices like thyratrons use ionized gas molecules to conduct electricity, at what speed are those ionized molecules travelling? Do the molecules need to travel at all?

Thanks!

Allan
 
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As you suspect, sparks consist of charged particles...often electrons, as in vacuum tubes, but any charged particles will do...as in ionized gases...even ionized air! They do NOT move anywhere near as fast as light which is electomagnetic radiation...maybe a few percent the speed of light. The actual speed of the charged particles depends on the design of the device, such as the separation distance of the charged plates and the potetial difference between charged plates.

I do not know typical speeds in vacuum tubes, but everyday lightning bolts [flashes] move at well over 100,000 miles per hour.
 
Thanks, for ionized gas I guess it is only the charge being transferred between molecules, and it is not necessary at all for the molecules to move from one plate to another. As for vacuum, I don't understand what slows the electrons down, I suppose a current flows through a wire at near the speed of light.
 

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