Polarity of magnetic field in a conducting wire

AI Thread Summary
When current flows through a conducting wire, such as copper, it generates a circular magnetic field without a specific polarity. The confusion arises from the distinction between a straight wire and an electromagnet; the latter creates a polarized magnetic field with defined north and south poles. Videos may misrepresent the behavior of magnetic fields around wires, as they do not exhibit polarity like electromagnets do. Understanding the difference between these two setups is crucial for grasping their respective magnetic interactions. Overall, the magnetic field around a current-carrying wire is circular and does not possess a defined polarity.
acrossingtwo
Messages
1
Reaction score
0
When current flows through a copper wire, for example, a magnetic field is produced. What is the polarity of that field? I've seen an example with special relativity and how a positive charge would be deflected. Does that mean the field is negative to a stationary object? Every video I watch says that a wire with current deflects a magnetic object. So then why does an electromagnet attract magnetic objects?

Thank you
 
Physics news on Phys.org
welcome to PF :smile:

acrossingtwo said:
When current flows through a copper wire, for example, a magnetic field is produced. What is the polarity of that field?

no idea what videos you were looking at but a magnetic field around a wire is circular so there is no particular polarity
Googling would have given you lots of images of that eg ...

View attachment 220505

View attachment 220506and a zillion more here /...

https://www.bing.com/images/search?...10444162&selectedindex=9&mode=overlay&first=1

so you see asking for a polarity isn't relevant :wink:
acrossingtwo said:
Every video I watch says that a wire with current deflects a magnetic object.

show us an example

acrossingtwo said:
So then why does an electromagnet attract magnetic objects?

A electromagnet is a different story to a straight wire carrying a current. An electromagnet is a coil of wire that may or nay not be wound around an iron core, and in that case the coil generates a polarised magnetic field in/around the coil and core with a N and S pole

have a read of this www site about electromagnets and their polarity

https://www.electronics-tutorials.ws/electromagnetism/electromagnets.html

Dave
 
Last edited:
I'm not a great fan of tricks for solving Physics problems, but since the direction of magnetic and electric fields is purely arbitrary, I do need a mnemonic to help me remember what was decided. Left and right hand rules never worked for me, because I needed another rule to remind me when to use L and when R!

For currents & magnetic fields my Physics teacher gave me a useful mnemonic, which works so long as your language uses N and S for magnetic poles.
magnetic_field.png

This is the face/end view of a coil or solenoid. If you want the field around a wire, just imagine yourself standing on one of the wires of the coil.
Of course, you do need to have a basic understanding of how these fields work in the first place. This is just to give you the sense of the field.
 

Attachments

  • magnetic_field.png
    magnetic_field.png
    2.3 KB · Views: 559

Thread 'Maxwell stress tensor'

This is from Griffiths' Electrodynamics, 3rd edition, page 352. I am trying to calculate the divergence of the Maxwell stress tensor. The tensor is given as ##T_{ij} =\epsilon_0 (E_iE_j-\frac 1 2 \delta_{ij} E^2)+\frac 1 {\mu_0}(B_iB_j-\frac 1 2 \delta_{ij} B^2)##. To make things easier, I just want to focus on the part with the electrical field, i.e. I want to find the divergence of ##E_{ij}=E_iE_j-\frac 1 2 \delta_{ij}E^2##. In matrix form, this tensor should look like this...
View full post »
Thread 'Applying the Gauss (1835) formula for force between 2 parallel DC currents'

Thread 'Applying the Gauss (1835) formula for force between 2 parallel DC currents'

Please can anyone either:- (1) point me to a derivation of the perpendicular force (Fy) between two very long parallel wires carrying steady currents utilising the formula of Gauss for the force F along the line r between 2 charges? Or alternatively (2) point out where I have gone wrong in my method? I am having problems with calculating the direction and magnitude of the force as expected from modern (Biot-Savart-Maxwell-Lorentz) formula. Here is my method and results so far:- This...
View full post »

Similar threads

B Magnetic field produced by an electric current
Replies
5
Views
2K
I Charge movement relative to magnetic field frame dependence/invariance
Replies
5
Views
915
I Question on Hall Effect and magnetic force
Replies
2
Views
2K
I The vector math of relative motion of wire-loop & bar magnet
Replies
1
Views
2K
I Faraday induction in constant B field, with non-conduction wires
Replies
2
Views
1K
I How induction works within a coil (nuances of it)
Replies
6
Views
2K
Why Doesn't Electric Force Cause Wires to Move?
Replies
15
Views
2K
I Can the Last Maxwell's Equation Explain Polarization of a Wire's Insulator?
Replies
3
Views
2K
I Magnetic field as result of length contraction
Replies
20
Views
4K
Conservation of Energy on Current-Carrying Wire in Magnetic Field
Replies
2
Views
1K

Hot Threads

Recent Insights

Back
Top