A closed curve encircles several conductors. The line integral ∮ B ⋅ d l \oint B\cdot dl around this curve is 3.83 × 10 − 4 T m 3.83\times10^{-4}\text{ T m} . If you were to integrate around the curve in the opposite direction, what would be the value of the line integral? Explain.

Hey everyone. So this problem is working with magnetic fields. It's asking us to consider a close loop that surrounds a long cable consisting consisting of cylinder shape conductors that are spaced apart by insulators. They give us the anti clockwise line integral value. And they're asking us to determine the value of the clockwise line integral, the same integral of B. D. L. Which is the magnitude of the magnetic field. So really this problem is just asking if you remember some of the basics of magnetic fields and their directions and their signs. So let's just recall that the magnitude of a counterclockwise um line integral is the opposite of that same line in a girl in the clockwise direction. And that's really all we need to remember for this problem. So our counterclockwise um value is 1.27 times 10 to the negative to Tesla meters, which means that our clockwise value, this is what we're searching. This is what we're looking for is the opposite of that. So clockwise is negative 1.27 times 10 to the negative to Tesla m. And we look at our possible answers. That's answer a That's all we have for this problem. See you in the next video

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29. Sources of Magnetic Field

Ampere's Law (Calculus)

Physics

29. Sources of Magnetic Field

Ampere's Law (Calculus)

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1:53 minutes

Problem 41b

Textbook Question

A closed curve encircles several conductors. The line integral $\oint B \cdot d l$ around this curve is $3.83 \times 10^{- 4} T m$ . If you were to integrate around the curve in the opposite direction, what would be the value of the line integral? Explain.

Verified step by step guidance

Understand the concept of line integral of a magnetic field: The line integral of the magnetic field $ \oint \mathbf{B} \cdot d\mathbf{l} $ around a closed curve is related to the net current enclosed by the curve, according to Ampère's Law.

Recognize the significance of direction: The direction of integration around the curve affects the sign of the line integral. If you reverse the direction of integration, the sign of the integral will also reverse.

Apply Ampère's Law: Ampère's Law states that $ \oint \mathbf{B} \cdot d\mathbf{l} = \mu_0 I_{enc} $, where $ I_{enc} $ is the net current enclosed by the curve. The given integral value is $ 3.83 \times 10^{-4} $ T m.

Consider the effect of reversing the direction: If the original integral value is positive, reversing the direction of integration will make the integral value negative, and vice versa.

Conclude the result: Therefore, if you integrate around the curve in the opposite direction, the value of the line integral will be $ -3.83 \times 10^{-4} $ T m.

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Key Concepts

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

Ampère's Law

Ampère's Law relates the magnetic field around a closed loop to the electric current passing through the loop. It states that the line integral of the magnetic field B along a closed path is equal to the permeability of free space times the total current enclosed by the path. This principle is crucial for understanding how the magnetic field behaves around conductors.

Line Integral

A line integral involves integrating a vector field along a curve. In the context of magnetic fields, it calculates the total magnetic influence along a path. The direction of integration affects the sign of the result, as reversing the path direction changes the sign of the integral, which is essential for understanding the problem's requirement to integrate in the opposite direction.

Direction of Integration

The direction of integration in a line integral is significant because it determines the sign of the result. When integrating a vector field like the magnetic field, reversing the direction of the path changes the sign of the integral. Thus, integrating in the opposite direction would yield the negative of the original value, which is a key aspect of the question.

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Textbook Question

(III) A coaxial cable consists of a solid inner conductor of radius R₁, surrounded by a concentric cylindrical tube of inner radius R₂ and outer radius R₃ (Fig. 28–45). The conductors carry equal and opposite currents I₀ distributed uniformly across their cross sections. Determine the magnetic field at a distance R from the axis for: (a) R < R₁; (b) R₁ < R < R₂; (c) R₂ < R < R₃; (d) R > R₃. (e) Let I₀ = 1.50 A, R₁ = 1.00 cm , R₂ = 2.00 cm , and R₃ = 2.50 cm Graph B from R = 0 to R = 3.00 cm.

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Multiple Choice

A solid, cylindrical conductor carries a uniform current density, J. If the radius of the cylindrical conductor is R, what is the magnetic field at a distance ? from the center of the conductor when r < R? What about when r > R?

A solid conductor with radius a is supported by insulating disks on the axis of a conducting tube with inner radius b and outer radius c (Fig. E28.43). The central conductor and tube carry equal currents I in opposite directions. The currents are distributed uniformly over the cross sections of each conductor. Derive an expression for the magnitude of the magnetic field at points outside the tube (r > c).

As a new electrical technician, you are designing a large solenoid to produce a uniform 0.150 T magnetic field near the center of the solenoid. You have enough wire for 4000 circular turns. This solenoid must be 55.0 cm long and 2.80 cm in diameter. What current will you need to produce the necessary field?

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Textbook Question

A long, hollow wire has inner radius R₁ and outer radius R₂. The wire carries current I uniformly distributed across the area of the wire. Use Ampère's law to find an expression for the magnetic field strength in the three regions 0 < r < R₁, R₁ < r < R₂, and R₂ < r.

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Textbook Question

An infinitely wide flat sheet of charge flows out of the figure in FIGURE CP29.83. The current per unit width along the sheet (amps per meter) is given by the linear current density J_s. Find the magnetic field strength at distance d above or below the current sheet.

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Textbook Question

What is the line integral of $\vec{B} \cdot \vec{d s}$ between points i and f in FIGURE EX29.19?

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Textbook Question

The value of the line integral of $\vec{B} \cdot \vec{d s}$ around the closed path in FIGURE EX29.21 is 1.38 x 10^-5 T m. What are the direction (into or out of the figure) and magnitude of I₃?

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A closed curve encircles several conductors. The line integral ∮B⋅dl\oint B\cdot dl around this curve is 3.83×10−4 T m3.83\times10^{-4}\text{ T m}. If you were to integrate around the curve in the opposite direction, what would be the value of the line integral? Explain.

Key Concepts

Ampère's Law

Line Integral

Direction of Integration

Watch next

A closed curve encircles several conductors. The line integral $\oint B \cdot d l$ around this curve is $3.83 \times 10^{- 4} T m$ . If you were to integrate around the curve in the opposite direction, what would be the value of the line integral? Explain.