It requires an external work of 4.67 X 10-6 J to move a negative charge between two charged parallel plates which are connected to a 12.0-volt battery. Calculate the negative charge's magnitude in microcoulombs, and indicate which way does the negative charge move( positive to negative/ or negative to positive)
It requires an external work of 4.67 X 10-6 J to move a negative charge between...
Part A If it takes +2.1×10−5 J to move a positively charged particle between two charged parallel plates, what is the charge on the particle if the plates are connected to a 12-V battery? Express your answer using two significant figures. q=? μC Part B Was it moved from the negative to the positive plate or from the positive to the negative plate? from the negative to the positive plate from the positive to the negative plate
6-11 please !!!
6. A positive charge of 6.0 x 10 coulomb is placed in an upward directed uniform electric field of 4.0 x 10^N/C. When the charge is moved 0.5 meter upward, the work done by the electric force on the charge is (A) 6 x 104J (B) 1.2 x 10°) (C)2 x 10^ J (D) 8 x 10^J (E) 12 x 10- J 7. Two parallel conducting plates are connected to a constant voltage source. The magnitude of...
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6. A positive charge of 6.0 x 10 coulomb is placed in an upward directed uniform electric field of 4.0 x 10*N/C. When the charge is moved 0.5 meter upward, the work done by the electric force on the charge is (A) 6 x 10*J (B) 1.2 x 10) (C)2 x 10*J (D) 8 x 10(E) 12 x 10J 7. Two parallel conducting plates are connected to a constant voltage source. The magnitude of the electric field between the...
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1. (8 points total) A parallel plate capacitor whose plates have area A and plate separation d is connected to a battery. While the capacitor remiains connected to the battery, describe quantitatively what will happen to the charge on the capacitor if each if the following actions occur. That is, explain numerically how the magnitude of the charge on the capacitor in each circumstance compares to the original a. (3 pts) The distance between...
The work done by an external force to move a -5.50 μC charge from point A to point B is 1.20×10−3 J . 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?
Please show full solutions.
Answers:
a) 1.416e-10 C
b) 12 V
c) -8.496e-10 J
Thanks!
A parallel plate capacitor with plate area A = 2 cm^2 and plate separation d = 0.3 mm is charged using a 24 V battery. Find the charge on each plate when the capacitor is fully charged. The capacitor is then disconnected from the battery and then a dielectric with dielectric constant of 2.0 is fully inserted between the plates. Calculate the resulting potential difference...
The work done by an external force to move a particle of charge -2.20 μC at constant speed from point A to point B is 6.40x10−310−3 J. (a) What is the difference between the electric potential energy of the charge at the two points? (b) What is the difference in the kinetic energy of the charge at the two points? (c) Determine the potential difference between the two points. (d) State which point is at the higher potential.
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Read Example 26.4 - Reconnection of Capacitors A Consider the following circuit. Let C= 14 F, C = 121F, and 4V = 30 Volt. Notice the capacitors are connected with their plates at opposite polarity. 511 10 1. Ifa 30 volt battery is used to charge each capacitor separately, what is the initial charge on each capacitor? QUE 2. Now consider the switches to be closed: esta G b a) Which way will charges move? b)...
Two parallel conducting plates are connected to a constant voltage source. The magntude of the electric field between the plates is 2506 N/C. If the voltage is doubled and the distance between the plates is reduced to 1 4 the original distance, what is the magnitude of the new electric field? Answer in units of N/C. A pair of oppositely charged parallel plates is separated by 5.36 mm. A potential difference of 582 V exists between the plates. What is...
An isolated parallel-plate capacitor (not connected to a battery) has a charge of Q = 1.7×10−5C. The separation between the plates initially is d = 1.2 mm, and for this separation the capacitance is 3.1×10−11F. Calculate the work that must be done to pull the plates apart until their separation becomes 2.6 mm, if the charge on the plates remains constant. The capacitor plates are in a vacuum. Express your answer using two significant figures. (unit in J)