A thin, horizontal, 10-cm-diameter copper plate is charged to ...

Question

A thin, horizontal, 10-cm-diameter copper plate is charged to 3.5 nC. If the charge is uniformly distributed on the surface, what are the strength and direction of the electric field 0.1 mm above the center of the top surface of the plate?

Accepted Answer

Hello, fellow physicists today, we're gonna solve the following practice problem together. So first off, let us read the problem and highlight all the key pieces of information that we need to use. In order to solve this problem, a flat circular object with neg thickness has a radius of 7.5 centimeters. The object is made of aluminum and has been negatively charged to 5.2 nano Coolum. Assuming the charge is evenly distributed across the surface, determine the electric fields magnitude and direction at a point 0.2 millimeters directly above the center of the object's top surface. So that's our end goals. We're trying to figure out what the electric fields magnitude and direction at a 0.0 0.2 millimeters directly above the center of the object's top surface. So that's our final answer that we're ultimately trying to solve for. Awesome. So looking at our multiple choice answers, let us note that the electric fields magnitude, which is our second answer is gonna be in the units of newtons per Coolum. And then our first half of the answer is gonna be saying how it's oriented direction wise. So is it gonna be towards the object or away from the object. So let's read them off to see what our final answer might be. So A is towards the object, 1.7 multiplied by 10 to the power of four B is towards the object 2.1 multiplied by 10 to the power of five C is away from the object, 1.7 multiplied by 10 to the power of five and D is away from the object 2.1 multiplied by 10 to the power of four newtons per poum. OK. First off, let us note that since half of the charge is on the top surface of the circular aluminum object and half is on the bottom of this object. Therefore, the surface charge density which we're gonna call this Ada can be written as we should be able to recall and write that Ada is equal to lowercase Q divided by capital A where Q is the charge and capital A is the area of a circle. So let's make, take a moment here to write off to the side that A or area of a circle is equal to pi multiplied by R squared. So now we can plug this value to our A A equation. So we'll be able to write that Ada is equal to Q divided by pi multiplied by R square. So now we can plug in all of our known variables to solve for Ada. So let us note that A A is equal to 5.2 multiplied by 10 to the power of negative nine cools means we have to take 5.2 nano cools and convert it to units of cools. And let us note that this is our whole value, but we need to divide it by two because we're focusing only on half of this sphere. Think of it like a sphere, a circular object. And we're, and so it, it's a flat, sorry not sphere. So it's a flat circular object. And since we're only dealing with half of it, that's why you have to divide by two. And now we need to divide this by pi multiplied by our radius squared, which is 0.075 m means we have to convert centimeters to meters. Awesome. And when we plug that into our calculator, we will get 1.47 multiplied by 10 to the power of negative seven coulombs per meter squared. Therefore, we can solve for the electric fields magnitude by recalling and using the following equation. So e the electric field is equal to a divided by epsilon zero where epsilon zero is the productivity of free space. So now we can plug in all of our known variables to solve for e our final answer. So we know that a theta is equal to 1.47 multiplied by 10 to the power of negative seven. And its units are Coombs per meter. Squared divided by the permittivity of free space, which we should be able to recall. And if not, you can quickly look this up is 8.85 multiplied by 10 to the power of negative 12 newtons per meter squared. So that's the numerical value for the permittivity of free space constant. So let me plug this into our calculator. We will get 1.66 multiplied by 10 to the power of four newtons per Coolum, which is approximately equal to 1.7 multiplied by 10 to the power of four newtons per Coolum when we round to one decimal place. And that's it. We've solved for this problem. Hooray, we did it. So since the charge on the circular aluminum object is negative, the direction of the electric field is towards the object. So we're just gonna, I'm just gonna put a box around towards. So that will mean so to so since it's towards the object, it will be in the downwards direction. So looking at our multiple choice answers, the correct answer has to be the letter A which is towards the object and 1.7 multiplied by 10 to the power of four newtons per coola. And that's it we've solved for this problem. Thank you so much for watching. Hopefully, that helped and I can't wait to see you in the next video. Bye.

A thin, horizontal, 10-cm-diameter copper plate is charged to 3.5 nC. If the charge is uniformly distributed on the surface, what are the strength and direction of the electric field 0.1 mm above the center of the top surface of the plate?

Key Concepts

Electric Field

Surface Charge Density

Gauss's Law

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