Electric Force Calculation Using Coulomb's Law | Problem 3, 9

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Two identical conductive spheres with charges of +13*10^-9 C and -14*10^-9 C are placed 0.34m apart and connected by a wire, leading to a discussion on calculating the electric force between them using Coulomb's Law. The equilibrium charge distribution is questioned, particularly whether to average the charges before applying Coulomb's Law. In a separate problem, three point charges are analyzed for the force on q_1 due to q_2 and q_3, emphasizing the importance of vector direction in calculating electric fields and forces. The discussion highlights the necessity of using Coulomb's Law for each charge separately and then applying the principle of superposition for net force calculation. A dipole approach is suggested as a simpler method for solving the problem involving the three charges.
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Problem 3.
Two identical conduction spheres are placed with their centers 0.34m apart. One is given a charge of +13*10^-9 C amd the other is given a charge of -14*10^-9 C. The spheres are connected by a conductiong wire.
After equilbrium has occured, find the electric force between the teo spheres. Answer in N.
Note: Would you add up the charges divide by two and the put it in Colulomb's law were it is the charged squared? From there find the electric force?

Problem 9.
Three point charges , q_1=+6.6 uC, q_2=+2.4uC, and q_3=-2.4uC, lie along the x-axis at x=ocm, x-2.4 cm, and x=5.3 cm, respectively.
a. What is the force exerted on q_1 by the two charges? (To right is positive) Use 8.99*10^9 N*m^2/C^2. Answer in N.
Note: How would put these values in Coulomb's law?
 
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yes for first part

Find the field at the point q1 due to q2 & q3 sayit is E

Then force will be q1E
 
re #9:

remember that E is a vector. THe "+" and "-" values that you get with Coulomb's equation do not tell you the direction is to the right or to the left. Draw a picture for E from q2 and from q3. IF they point in the same direction then the two E's add up. IF they point in different directions, then you subtract values, and the direction of the net E is the same as the larger E.
 
From Couloumbs law u can calculate the direction

the Vector form for Coulombs law is

<br /> \vec F = \frac{kq_1q_2}{\vec r^3} \vec r<br />

The thing is u have to put the sign of q1&q2 along with magnitude
 
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regarding question 9

To find magnitiude of the force of q_1 don't I use Coulomb's law twice. Once with the second charge to be 2.4uC and another time with second charge -2.7uC, with both charges being multiplyied with 6.6uC.
Then I will get two amounts whih i would multiply with what?
 
I was just giving the formula in vector form

U got it right u will have to do with charges

Got the force due to both charges say F1,F2

Apply the superposition Net force= F1+F2

Note you have to add vectors force is vector
 
Is the answer -190.1888733N.
 
U never get such an enormous force generally in Coulombs law or in Electrostatics

I just noticed there is a simple way of doing the problem

The given set of charges forms a dipole

U can use the equation of Field in axial line for a dipole
 

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