To separate a 0.35 C charge from another charge, 29 J of work is done. What...

The work done by an external force to move a -6.70 μC charge from point A to point B is 1.90×10−3 J . Part A...

The work done by an external force to move a -6.70 μC charge from point A to point B is 1.90×10−3 J . Part A If the charge was started from rest and had 4.90×10−4 J of kinetic energy when it reached point B, what must be the potential difference between A and B? Express your answer with the appropriate units. VB−VA= ?

The work done by an external force to move a -6.40 μC charge from point A...

The work done by an external force to move a -6.40 μC charge from point A to point B is 1.40×10−3 J . If the charge was started from rest and had 4.78×10−4 J of kinetic energy when it reached point B, what must be the potential difference between A and B? Express your answer with the appropriate units.

What is an electric potential? Discuss in terms of the work being done to a +...

What is an electric potential? Discuss in terms of the work being done to a + test charge being moved around in an electric field. Describe motion that produces no work.

1) a) A point charge 10 C is located at (1,0,0) and another charge of 40...

1) a) A point charge 10 C is located at (1,0,0) and another charge of 40 C is located at (10,0,0). Find a point on x-axis where voltage due to these two charges is zero. If a positive charge is brought to this point from space, how much work is done. b) A point charge -10 C is located at (1,0,0) and another charge of -40 C is located at (10,0,0). Find a point on x-axis where voltage due to...

A point charge q1 is held stationary at the origin. A second charge q2 is placed...

A point charge q1 is held stationary at the origin. A second charge q2 is placed at point a, and the electric potential energy of the pair of charges is +5.7 * 10-8 J. When the second charge is moved to point b, the electric force on the charge does -1.6 * 10-8 J of work. What is the electric potential energy of the pair of charges when the second charge is at point b?

In a constant uniform electric field, a particle with charge −100 ?? is moved from the...

In a constant uniform electric field, a particle with charge −100 ?? is moved from the origin a distance ? = 0.80 ? straight in the direction of the electric field lines. The field has a strength of 5.0 ? ? . a) What is the voltage difference between the initial and final position? b) How much work is done to move the charge? c) Does the charge gain or lose electrical potential energy in the process of this move?...

A proton is acted on by an uniform electric field of magnitude 313 N/C pointing in...

A proton is acted on by an uniform electric field of magnitude 313 N/C pointing in the negative y direction. The particle is initially at rest. (a) In what direction will the charge move? (b) Determine the work done by the electric field when the particle has moved through a distance of 2.45 cm from its initial position. J (c) Determine the change in electric potential energy of the charged particle. J (d) Determine the speed of the charged particle....

A 4.5 kg block of aluminum is heated from 29?C to 97?C at atmospheric pressure. Find...

A 4.5 kg block of aluminum is heated from 29?C to 97?C at atmospheric pressure. Find the work done by the aluminum. Assume the density of aluminum is 2700 kg/m3 and the thermal coefficient of expansion is 2.4 × 10?5 ( ?C)?1 . Answer in units of J Find the amount of energy transferred to it by heat. Assume the specific heat of aluminum is 900 J/kg · ? C. Answer in units of J. Find the increase in its...

Please work out on paper 16.5 A 4.7 μC point charge is held fixed at the...

Please work out on paper 16.5 A 4.7 μC point charge is held fixed at the origin. a) What is the electric potential difference between a point 20 cm from the 4.7 μC charge and a point 70 cm away from the 4.7 μC charge? b) If a 8 nC charge is released at point a, what is the change in potential energy of the 8 nC charge as it passes point b? c) If the mass of the 8...

A +3.0-nC charge Q is initially at rest a distance of 10 cm ( r1 )...

A +3.0-nC charge Q is initially at rest a distance of 10 cm ( r1 ) from a +5.0-nC charge q fixed at the origin. Naturally, the Coulomb force accelerates Q away from q, eventually reaching 15 cm ( r2 ). The charge Q is repelled by q, thus having work done on it and losing potential energy. What is the work done by the electric field between r1 and r2 ? What is the change in the potential energy...