Does a straight wire or Electron have a north and south magnetic pole?

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A straight wire does not have distinct magnetic north and south poles like a coil or bar magnet; instead, it generates a symmetrical magnetic field around it. The attraction or repulsion between two wires depends on the direction of their currents, with opposite currents attracting and the same currents repelling. Electrons in motion also create a magnetic field, but this field is continuous and does not exhibit localized poles. Magnetic field lines are continuous, lacking definitive starting or ending points, unlike electric charges. Overall, magnetic fields differ fundamentally from electric fields in their characteristics and behavior.
nemesiswes
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So does a wire actually have a magnetic north and south pole? I know a coil of wire will form one but a straight wire will only attract another wire if the other wire's current is going in the opposite direction and repel if in the same direction. I have looked for images and they always just show a magnetic field circling the wire with no apparent end like a bar magnet or coil of wire has.


2nd.
Does a electron in motion have a magnetic north or south?
 
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You need to ask yourself what a magnetic pole is. What is it about a coil that produces 'poles'? You could even ask 'where' the actual pole of a coil of wire is. You have seen pictures of the field lines around various arrangements of wires and magnets.
Magnetic lines of flux are continuous and it's only in localised regions where they are closer together that we can identify a magnetic pole.
Straight wires and traveling electrons will generate a field but that field is symmetrical around the line of charge flow and are not 'scrunched up' anywhere.
 
So then that is why it is said that magnetic fields don't end or start at anywhere? Electric charges have a start point and end point obviously but then a magnetic field doesn't actually have any start or end right?
 
Correct. The two fields are very different in that respect.
 

Thread 'Reflections at the source point of a transmission line.'

I was using the Smith chart to determine the input impedance of a transmission line that has a reflection from the load. One can do this if one knows the characteristic impedance Zo, the degree of mismatch of the load ZL and the length of the transmission line in wavelengths. However, my question is: Consider the input impedance of a wave which appears back at the source after reflection from the load and has traveled for some fraction of a wavelength. The impedance of this wave as it...
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