A 2.0-mm-diameter wire formed from a composite material has a resistivity that decreases with distance along the wire as ρ=ρ₀e −αx , where ρ₀=4.0×10 −5 Ω m, x (in m) is measured from one end of the wire, and the constant α=4.0 m −1 . What is the resistance of a 50-cm-long length of this wire?

Welcome back, everyone. We are looking to create a customized resistance profile of a given wire. Now we are told that this wire is aligned in the y direction and that it has a radius of 1.5 millimeters. Now we will want this in meters. So I'm going to multiply this by 10 raised to the power of negative three. Now we are told that the length of the wire is going to be centimeters. Once again, we will want meters. So I will multiply this by 10 rays to the power of negative two. And we are tasked with finding what is the resistance given by this fire. Now, before we get started here, I do wish to acknowledge the multiple choice answers over on the left hand side of the screen, those are gonna be the values in which we strive for. So without further ado let us begin. Well, if you'll notice in one bit of information that I wish to highlight that we are given the resistivity by the following underlined expression. Now, what we can do is we can say that the resistance is equal to the integral of the derivative of resistance. Now, derivative of resistance is equal to the resistivity with respect to Dy divided by the cross sectional area of the wire. Now let me go ahead and plug this into our equation. And what we get is that one over the area, it's a constant. We can take it out of the integral multiplied by the integral over the length of the wire. So 02.3 multiplied by our resistivity expression with respect to Dy will give us our resistance. Let's go ahead and fill that in. We have 2.7 multiplied by 10. Raised to the negative fourth power multiplied by E raised to the negative of 3.5 divided by M multiplied by Y all with respect to Y let's go and form this inter here. And what we get is negative 2.7 multiplied by 10 raised to the negative fourth power divided by our area of I multiplied by 1. multiplied by 10, raised to the negative third power squared multiplied by 3.5 divided by M all of that multiplied by E raced to the negative 3.5 divided by M multiplied by Y which we have to evaluate from zero to 0.3. What this gives us is negative 2.7 multiplied by 10, raised to the negative fourth power divided by I multiplied by 1.5 multiplied by 10, raised to the negative third power raised to the second power multiplied by 3. per meter, all multiplied by E raised to the negative 3.5 divided by M multiplied by 0.3 minus E to the negative 3.5 divided by M multiplied by zero. Evaluating this. What we get for our resistance is 7.1. S corresponding to our final answer. Choice of B Thank you all so much for watching. I hope this video helped. We will see you all in the next one.

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27. Resistors & DC Circuits

Resistors and Ohm's Law

Physics

27. Resistors & DC Circuits

Resistors and Ohm's Law

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3:42 minutes

Problem 66

Textbook Question

A 2.0-mm-diameter wire formed from a composite material has a resistivity that decreases with distance along the wire as ρ=ρ₀e^−αx, where ρ₀=4.0×10⁻⁵ Ω m, x (in m) is measured from one end of the wire, and the constant α=4.0 m⁻¹. What is the resistance of a 50-cm-long length of this wire?

Verified step by step guidance

Step 1: Understand the problem. The wire has a resistivity that varies along its length according to the formula ρ = ρ₀e^−αx, where ρ₀ is the initial resistivity, α is a constant, and x is the distance from one end of the wire. We need to calculate the total resistance of a 50-cm-long wire, taking into account the varying resistivity.

Step 2: Recall the formula for resistance. Resistance R is given by the integral of resistivity ρ over the length of the wire, divided by the cross-sectional area A. Mathematically, R = ∫(ρ(x)/A) dx, where A = πr² is the cross-sectional area of the wire, and r is the radius of the wire.

Step 3: Calculate the cross-sectional area of the wire. The diameter of the wire is given as 2.0 mm, so the radius r = diameter/2 = 1.0 mm = 1.0 × 10^−3 m. Substitute this into A = πr² to find the area.

Step 4: Set up the integral for resistance. Substitute ρ(x) = ρ₀e^−αx and A = πr² into the formula for resistance: R = ∫(ρ₀e^−αx / πr²) dx. The limits of integration are from x = 0 to x = 0.50 m (since the wire is 50 cm long).

Step 5: Solve the integral. The integral of e^−αx with respect to x is (1/α)e^−αx. Apply the limits of integration (from 0 to 0.50 m) to find the total resistance R. Simplify the expression to get the final formula for R in terms of ρ₀, α, and the wire's dimensions.

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Key Concepts

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

Resistivity

Resistivity is a material property that quantifies how strongly a given material opposes the flow of electric current. It is denoted by the symbol ρ and is measured in ohm-meters (Ω·m). In this problem, the resistivity of the wire varies with distance, which affects the overall resistance of the wire segment.

Resistance Calculation

Resistance (R) is calculated using the formula R = ρL/A, where ρ is the resistivity, L is the length of the conductor, and A is the cross-sectional area. For a cylindrical wire, the cross-sectional area can be determined using A = π(d/2)², where d is the diameter. In this case, the resistance must be integrated along the length of the wire due to the varying resistivity.

Integration in Physics

Integration is a mathematical technique used to find the total value of a quantity that varies over a certain range. In this context, it is necessary to integrate the resistance contributions along the length of the wire, as the resistivity changes with distance. This allows for the calculation of the total resistance of the wire segment by summing the infinitesimal resistances over its length.

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