How Is the Magnetic Field Calculated Near a Current-Carrying Wire?

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SUMMARY

The magnetic field near a current-carrying wire can be calculated using the formula B = μ₀I/(2πr). In this discussion, a straight wire carrying a current of 42 A is analyzed, with the magnetic field estimated at a distance of 4.2 cm from the wire, resulting in a magnetic field strength of 0.20 mT. The solenoid, which has a diameter of 6.6 cm and carries a current of 6.0 A, does not contribute to the magnetic field at this distance, as the point of interest lies outside its radius. The magnetic field outside the solenoid is zero, confirming that only the straight current influences the magnetic field at this location.

PREREQUISITES
  • Understanding of magnetic fields and their calculations
  • Familiarity with Ampère's Law
  • Knowledge of solenoid properties and formulas
  • Basic algebra for manipulating equations
NEXT STEPS
  • Study the derivation of the magnetic field around a straight conductor
  • Learn about the properties of solenoids and their magnetic fields
  • Explore the application of Ampère's Law in various configurations
  • Investigate the effects of multiple current-carrying wires on magnetic fields
USEFUL FOR

Physics students, electrical engineers, and anyone interested in electromagnetism and magnetic field calculations.

SimonZ
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Homework Statement


A straight wire carrying a current of 42 A lies along the axis of a 6.6 cm-diameter solenoid. The solenoid is 70 cm long and has 250 turns carrying a current of 6.0 A.
Estimate the magnitude of the magnetic field 4.2 cm from the wire.


Homework Equations


magnetic field due to a straight current I
B = mu_0*I/(2*pi*r)


The Attempt at a Solution


Note 4.2 cm > radius 3.3 cm, so the point is outside the solenoid, the magnetic field is only due to the straight current
use I = 42 A, r = 4.2 cm, get B = 0.20 mT
Anything wrong?
 
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SimonZ said:
Note 4.2 cm > radius 3.3 cm, so the point is outside the solenoid, the magnetic field is only due to the straight current
use I = 42 A, r = 4.2 cm, get B = 0.20 mT
Anything wrong?


SimonZ said:
The solenoid is 70 cm long and has 250 turns carrying a current of 6.0 A.

The solenoid carries a current, so it has a magnetic field. For a solenoid

B=\mu_0nI \ where \ n=\frac{No. \ of \ turns}{Length \ of \ solenoid}


So you'd need to find the resultant mag. field of the solenoid and the straight conductor.
 
B = μo(N/l) * I = μonI
is only valid for magnetic field INSIDE the solenoid.
The field OUTSIDE the solenoid is zero.
So the field is only due to the straight current
 

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