Consider two separate systems with four charges of the same magnitude q = 17 µC arranged in the vertexesof a square of length h = 20 cm, see the picture below. Calculate the electric potential at the center of thesquare (points A and C) and at the middle of the bottom side of the square (points B and D).yyqhqhA.BThe potential at point A, VA =The potential at point B, VB =The potential at point C, Vc ==The potential at point D, VĎ :qqXUnits VUnits VUnits VUnits VUnits JqUnits JFhCc.ᎠHow much work is required to move a -38 µC charge from point A to point B?The work required, Wä→ß =How much work is required to move a -38 µC charge from point C to point D?The work required, Wc→D =✓✓.✓✓.q-qOX

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Consider two separate systems with four charges of the same magnitude q = 17 µC arranged in the vertexes of a square of length h = 20 cm, see the picture below. Calculate the electric potential at the center of the square (points A and C) and at the middle of the bottom side of the square (points B and D). y y q q h HH c. h D q q h A B h The potential at point A, VA = The potential at point B, VB = The potential at point C, Vc = Units V Units V Units V The potential at point D, V₁ = How much work is required to move a -38 μC charge from point A to point B? The work required, WA→B = How much work is required to move a -38 µC charge from point C to point D? The work required, Wc→D = Units V Units J Units J -q

Consider two separate systems with four charges of the same magnitude q = 17 µC arranged in the vertexes of a square of length h = 20 cm, see the picture below. Calculate the electric potential at the center of the square (points A and C) and at the middle of the bottom side of the square (points B and D). y y q q h HH c. h D q q h A B h The potential at point A, VA = The potential at point B, VB = The potential at point C, Vc = Units V Units V Units V The potential at point D, V₁ = How much work is required to move a -38 μC charge from point A to point B? The work required, WA→B = How much work is required to move a -38 µC charge from point C to point D? The work required, Wc→D = Units V Units J Units J -q

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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Question

Consider two separate systems with four charges of the same magnitude q = 17 µC arranged in the vertexes
of a square of length h = 20 cm, see the picture below. Calculate the electric potential at the center of the
square (points A and C) and at the middle of the bottom side of the square (points B and D).
y
y
q
h
q
h
A.
B
The potential at point A, VA =
The potential at point B, VB =
The potential at point C, Vc =
=
The potential at point D, VĎ :
q
q
X
Units V
Units V
Units V
Units V
Units J
q
Units J
F
h
C
c.
Ꭰ
How much work is required to move a -38 µC charge from point A to point B?
The work required, Wä→ß =
How much work is required to move a -38 µC charge from point C to point D?
The work required, Wc→D =
✓✓.
✓✓.
q
-q
O
X

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