Question

Consider three identical metal spheres, A, B, and C. Sphere A carries a charge of +6q. Sphere B caries a charge of-2q. Sphere C carries no net charge. Spheres A and B are touc separated. Sphere C is then touched to sphere A and separated from it. Last, sphere C is to sphere B and separated from it. hed together and then uched to 20. How much charge is on sphere B after A and B touch and are separated? 21. How much charge ends up on sphere C? on the three spheres (b) before they are allowed to touch cach other? three 22. What is the total charge A) +1q

Answer 1

20. How much charge is on sphere B after A and B touch and are separated?

Answer:

`\boxed{q_(B)=+2q}`

Step-by-step explanation:

We'll solve this problem by using the concept of electric potential or simply called potential
`V`, which is the energy per unit charge, so the potential
`V` at any point in an electric field with a test charge
`q_(0)` at that point is:

`V=(U)/(q_(0))`

The potential
`V` due to a single point charge q is:

`V=k(q)/(r)`

Where
`k` is an electric constant,
`q` is value of point charge and
`r` is the distance from point charge to where potential is measured. Since, the three spheres A, B and C are identical, they have the same radius
`r`. Before the sphere A and B touches we have:

`V_(A)=k(q_(A))/(r_(A)) \\ \\ V_(B)=k(q_(B))/(r_(A)) \\ \\ But: \\ \\ \ r_(A)=r_(B)=r`

When they touches each other the potential is the same, so:

`V_(A)= V_(B) \\ \\ k(q_(A))/(r)=k(q_(B))/(r) \\ \\ \boxed{q_(A)=q_(B)}`

From the principle of conservation of charge the algebraic sum of all the electric charges in any closed system is constant. So:

`q_(A)+q_(B)=q \\ \\ q_(A)=+6q \ and \ q_(B)=-2q \\ \\ So: \\ \\ \boxed{q_(A)+q_(B)=+4q}`

Therefore:

`(1) \ q_(A)=q_(B) \\ \\ (2) \ q_(A)+q_(B)=+4q \\ \\ (1) \ into \ (2): \\ \\ q_(A)+q_(A)=+4q \therefore 2q_(A)=+4q \therefore \boxed{q_(A)=q_(B)=+2q}`

So after A and B touch and are separated the charge on sphere B is:

`\boxed{q_(B)=+2q}`

21. How much charge ends up on sphere C?

Answer:

`\boxed{q_(C)=+1.5q}`

Step-by-step explanation:

First: A and B touches and are separated, so the charges are:

`q_(A)=q_(B)=+2q`

Second: C is then touched to sphere A and separated from it.

Third: C is to sphere B and separated from it

So we need to calculate the charge that ends up on sphere C at the third step, so we also need to calculate step second. Therefore, from the second step:

Here
`q_(A)=+2q` and C carries no net charge or
`q_(C)=0`. Also,
`r_(A)=r_(C)=r`

`V_(A)=k(q_(A))/(r) \\ \\ V_(C)=k(q_(C))/(r)`

Applying the same concept as the previous problem when sphere touches we have:

`k(q_(A))/(r) =k(q_(C))/(r) \\ \\ q_(A)=q_(C)`

For the principle of conservation of charge:

`q_(A)+q_(C)=+2q \\ \\ q_(A)=q_(C)=+q`

Finally, from the third step:

Here
`q_(B)=+2q \ and \ q_(C)=+q`. Also,
`r_(B)=r_(C)=r`

`V_(B)=k(q_(B))/(r) \\ \\ V_(C)=k(q_(C))/(r)`

When sphere touches we have:

`k(q_(B))/(r) =k(q_(C))/(r) \\ \\ q_(B)=q_(C)`

For the principle of conservation of charge:

`q_(B)+q_(C)=+3q \\ \\ q_(A)=q_(C)=+1.5q`

So the charge that ends up on sphere C is:

`q_(C)=+1.5q`

22. What is the total charge on the three spheres before they are allowed to touch each other.

Answer:

`+4q`

Step-by-step explanation:

Before they are allowed to touch each other we have that:

`q_(A)=+6q \\ \\ q_(B)=-2q \\ \\ q_(C)=0`

Therefore, for the principle of conservation of charge the algebraic sum of all the electric charges in any closed system is constant, then this can be expressed as:

`q_(A)+q_(B)+q_(C)=+6q -2q +0 \\ \\ \therefore q_(A)+q_(B)+q_(C)=+4q`

Lastly, the total charge on the three spheres before they are allowed to touch each other is:

`+4q`