What is the electric field strength

In summary, the electric field at a point 2.7 cm to the left of the middle charge is 1.733218664*10^7 N/C.
  • #1
mustang
169
0
Problem 16.
Three charges: +8.2uC 4.8 cm to the left of 4uC and a -2.3uC 2.1 cm to the right of the 4uC charge.
What is the electric field strength at a point 2.7cm to the left of the middle charge? In N/C.
Note" Is the answer 1.733218664*10^7 from the 8.99*10^9 (4*10^-6)/(0.027^2)=49327846.36 and (8.99*10^9)(8.2*10^-6)/(0.048^2)=31995659.72 which were subtracted to get that answer.
 
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  • #2
You might want to look that over again.

For starters, there are 3 charges & you figured the field from only 2 (& got one of the distances wrong).

Draw a diagram first, & work from that.
 
  • #3
I drew a diagram and have 8.2 uC 2.1 cm away from the point that is 2.7 cm to the left of the middle charge. In addition should i multiply 8.99*10^9 to -2.3uC divided by 3.1 cm and subtract what is now three values to get my answer?
 
  • #4
First, where did you get 3.1 cm?

Second, make sure you keep the directions straight. The field from the positive 8.2 μC charge is directed toward the right. What are the directions of the other two fields?
i.e.: same direction = add; opposite direction = subtract

And don't forget, you are dividing by the square of the distance.
 
  • #5
woops! From -2.3uC to 4 uC is 2.1cm and from 4 uC it is 2.7 cm to reach that point so the distance would be 4.8cm. So for -2.3uC I multiply 8.99*10^9 to -2.3uC divided by 4.8 cm or 0.048m?
 
  • #6
.0482

But think carefully about the directions. It's not just a question of the sign of the charge. You have to consider the relative positions of the particles.
 
  • #7
The field from the +8.2 μC charge has the same direction at point P as the -2.3 μC charge.

Do you see why?
 
  • #8
No, i don't see why 8.2uC and -2.3uC have the same direction. I got three values from 4*106-6 is 49327846.36, from 8.2*10^-6 is 167160997.7, and -2.3*10^-6 is 8974392.361. So would i add 167160997.7 to 8974392.361 and subtract that from 167160997.7/
 
  • #9
No.

The direction of the electric field at any point P is the same as the direction of the electrical force that would be experienced by a positive "test" charge placed at that point.

In this problem, if you placed a positive test charge at point P, it would be repelled by the positive 8.2 μC charge (call that charge A) towards the right since they're both positive, so the component of the field from charge A at point P is directed toward the right.

But the negative 2.3 μC charge (call it C) would ATTRACT a positive charge, so a positive test charge located at point P would be pulled to the right. Therefore, the field component produced by charge C at point P is also directed toward the right.

Therefore, the field components of charges A and C at point P are added, not subtracted.

On the other hand, what would charge B (the +4 μC charge in the middle) do to a positive test charge at point P?

Get it?
 
  • #10
Are the three values I got from the charges right?
 
  • #11
Yes. Now you just have to figure out what to add & what to subtract.
 
  • #12
So gnome since you said that "The field from the +8.2 ìC charge has the same direction at point P as the -2.3 ìC charge." I would add
167160997.7 to 8974392.361 to get 176135390.1. From that I would subtract 49327846.36 and get 126807543.7, right?
 
  • #13
Yes, but do you understand why, or are you just taking my word for it?
 

1. What is the definition of electric field strength?

The electric field strength is a measure of the force per unit charge exerted on a stationary, positive test charge placed in an electric field. It is represented by the symbol E and is measured in units of volts per meter (V/m).

2. How is electric field strength different from electric potential?

Electric field strength and electric potential are related, but they are not the same. Electric potential is a scalar quantity that represents the potential energy per unit charge at a certain point in an electric field. Electric field strength, on the other hand, is a vector quantity that represents the direction and magnitude of the force per unit charge at a certain point in an electric field.

3. What factors affect the strength of an electric field?

The strength of an electric field can be affected by several factors, including the distance between charges, the magnitude of the charges, and the medium in which the charges are located. The electric field strength is inversely proportional to the square of the distance between charges and directly proportional to the magnitude of the charges.

4. How is electric field strength measured?

Electric field strength is typically measured using a device called an electric field sensor or probe. The sensor measures the electric force experienced by a test charge placed at a specific point in the electric field. The measured force is then divided by the magnitude of the test charge to determine the electric field strength at that point.

5. What are some real-world applications of electric field strength?

Electric field strength plays a crucial role in many aspects of our daily lives, including the functioning of electronic devices, the operation of power grids, and the behavior of lightning strikes. It is also used in medical procedures such as electrocardiograms and electroencephalograms to measure the electrical activity in the body.

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