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The formula corresponds to
A. The strength of an electric field between two charged particles.
B. The electric flux across a surface
C. The electric potential between two charged particles.
D. The electric potential energy between two charged particles.
E. The electric force between two charged particles.
The stre
ngth of a
n electric.
..
The electric
flux acro
ss a ...
The electric
potential be...
The electric
potential en...
The electric
force
betwe..
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The abbreviation for the SI unit of electric potential is:
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The abbreviation for the SI unit of capacitance is:
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The capacitance of a parallel-plate capacitor in vacuum depends on the potential difference between the plates.
A. TrueB. False
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Two capacitors are in ______ on the left, and in _______ on the right
A. series, parallelB. parallel, seriesC. series, seriesD. parallel, parallel 0% 0%0%0%
Given two identical parallel-plate capacitors, how should they be connected to increase the capacitance of the system consisting of both capacitors?A. SeriesB. ParallelC. Either one
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In a series connection, the magnitude of the charge on all of the plates is the same. This is due to….
A. Gauss’s LawB. Conservation of
chargeC. Principle of
superpositionD. Coulomb’s Law
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When capacitors are connected in series, the charges are the same on the capacitors and the potential differences add. In parallel, the potential differences are the same and the charges add.
A. TrueB. False
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The potential difference across ab is 50.0 V. Compute the equivalent capacitance of the system (in µF).
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The potential difference across ab is 50.0 V and the equivalent capacitance of the system is 3.47 µF. How much charge is stored by these capacitors (in µC)?
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The potential difference across ab is 50.0 V and the equivalent capacitance of the system is 3.47 µF. How much charge is stored by the 10 µF capacitor (in µC)?
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