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28. Magnetic Fields and Forces

Magnetic Force on Current-Carrying Wire

Physics

28. Magnetic Fields and Forces

Magnetic Force on Current-Carrying Wire

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3:09 minutes

Problem 15

Textbook Question

(III) A curved wire, connecting two points a and b, lies in a plane perpendicular to a uniform magnetic field $\vec{B}$ and carries a current I. Show that the resultant magnetic force on the wire, no matter what its shape, is the same as that on a straight wire connecting the two points carrying the same current I. See Fig. 27–44.

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The magnetic force on a current-carrying wire in a magnetic field is given by the formula: **F = I ∫ (dl × B)**, where **dl** is the infinitesimal vector element of the wire, **B** is the magnetic field vector, and **×** represents the cross product.

The key observation here is that the magnetic field **B** is uniform and constant in magnitude and direction. This allows us to treat **B** as a constant vector throughout the integration process.

The integral **∫ (dl × B)** can be rewritten as **B × ∫ dl**, because the cross product with a constant vector can be factored out of the integral. This simplifies the problem to evaluating the integral of **dl**, which represents the vector sum of all infinitesimal elements of the wire.

The vector sum **∫ dl** is simply the displacement vector from point **a** to point **b**, regardless of the shape of the wire. This is because the integral of **dl** over a path gives the net displacement between the start and end points.

Thus, the magnetic force becomes **F = I (B × d)**, where **d** is the straight-line displacement vector from **a** to **b**. This shows that the resultant magnetic force depends only on the endpoints of the wire and not on its shape, proving that the force on the curved wire is the same as that on a straight wire connecting the two points.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Magnetic Force on a Current-Carrying Wire

The magnetic force experienced by a current-carrying wire in a magnetic field is given by the equation F = I(L × B), where F is the force, I is the current, L is the length vector of the wire, and B is the magnetic field vector. This force is perpendicular to both the direction of the current and the magnetic field, resulting in a force that can vary depending on the wire's orientation and shape.

Biot-Savart Law

The Biot-Savart Law describes the magnetic field generated by a current-carrying conductor. It states that the magnetic field dB at a point in space due to a small segment of current-carrying wire is proportional to the current and the length of the segment, and inversely proportional to the square of the distance from the segment to the point. This law helps in understanding how the shape of the wire affects the resultant magnetic field and force.

Superposition Principle

The superposition principle in physics states that the total force acting on an object is the vector sum of all individual forces acting on it. In the context of a curved wire in a magnetic field, this principle allows us to analyze the magnetic forces on infinitesimal segments of the wire and sum them up to find the total force, demonstrating that the resultant force on a curved wire can be equivalent to that on a straight wire connecting the same endpoints.

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Textbook Question

A stiff wire 50.0 cm long is bent at a right angle in the middle. One section lies along the z axis and the other is along the line y = 2x in the xy plane. A current of 20.0 A flows in the wire—down the z axis and out the wire in the xy plane. The wire passes through a uniform magnetic field given by = (0.285î ) T. Determine the magnitude and direction of the total force on the wire.

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Textbook Question

The force on a wire carrying 6.45 A is a maximum of 1.64 N when placed between the pole faces of a magnet. If the pole faces are 55.5 cm in diameter, what is the approximate strength of the magnetic field?

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Textbook Question

The power cable for an electric trolley (Fig. 27–60) carries a horizontal current of 330 A toward the east. The Earth’s magnetic field has a strength 5.0 x 10^-5 T and makes an angle of dip of 22° at this location. Calculate the magnitude and direction of the magnetic force on a 15-m length of this cable.

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Textbook Question

(II) A current-carrying circular loop of wire (radius r, current I) is partially immersed in a magnetic field of constant magnitude B₀ directed out of the page as shown in Fig. 27–43. Determine the net force on the loop due to the field in terms of θ₀. (Note that θ₀ points to the dashed line, above which B = 0.)

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Textbook Question

A uniform conducting rod of length ℓ and mass m sits atop a fulcrum, which is placed a distance ℓ/4 from the rod’s left-hand end and is immersed in a uniform magnetic field of magnitude B directed into the page (Fig. 27–54). An object whose mass M is 7.0 times greater than the rod’s mass is hung from the rod’s left-hand end. What current (direction and magnitude) should flow through the rod in order for it to be “balanced” (i.e., be at rest horizontally) on the fulcrum? (Flexible connecting wires which exert negligible force on the rod are not shown.)

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Multiple Choice

Two long wires carry 16 A currents in the directions shown in Figure 1. One wire is 10 cm above the other. What is the direction of the magnetic field at a point equidistant from both wires?

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Multiple Choice

A 5-m current-carrying wire (red line) is ran through a 4 T magnetic field (blue lines), as shown. The angle shown is 30°. What must the magnitude and direction of the current in the wire be when it feels a 3 N force directed into the page?

Suppose a certain type of wire has a length of