Three charges are at three corners of a rectangle with side L1 = 7 m and L2 =...

Three point charges q1, q2, and q3 are situated at three corners of a rectangle as...

Three point charges q1, q2, and q3 are situated at three corners of a rectangle as shown in the diagram below. Here q1 = +9.00 µC, q2 = −9.00 µC, q3 = +2.00 µC. https://www.webassign.net/webassignalgphys1/19-p-026.gif (a) What is the electric potential at the free corner where there is no charge? V (b) What charge should be placed at the free corner for the electric potential at the center of the rectangle to be zero? Include both magnitude and sign if...

The figure below shows three small, positively charged spheres at three corners of a rectangle. The...

The figure below shows three small, positively charged spheres at three corners of a rectangle. The particle at upper left has a charge q1 = 6.00 nC, the one at the lower left has a charge of q2 = 7.00 nC, and the one at lower right has a charge q3 = 3.00 nC. The rectangle's horizontal side has length x = 5.50 cm and its vertical side has length y = 3.50 cm. Three positive charges lie at three...

Three point charges q1=1 μC , q2=2 μC and q3=-3 μC are located at three corners...

Three point charges q1=1 μC , q2=2 μC and q3=-3 μC are located at three corners of a square of side a=2 cm . Charge q3 is located diagonally opposed to the empty corner of the square. Calculate the electric potential created by the three charges at the empty corner of the square. Calculate the work done by the electric field of the three charges when a fourth charge q4=-4 μC moves from the center of the square to the...

The figure shows three charges q1, q2 and q3 situated at corners of a rectangle of...

The figure shows three charges q1, q2 and q3 situated at corners of a rectangle of sides a = 15.0 cm and b = 7.0 cm. 1) For q1 = 5.80 μC, q2 = -5.80 μC, and q3 = 2.30 μC find the electric potential at the center of the rectangle. 2) Continuing with the figure above, how much of the electric energy of the system would be expended in moving q3 to infinity while q1 and q2 remain in...

Three charges are at the corners of an equilateral triangle, as shown in the figure below....

Three charges are at the corners of an equilateral triangle, as shown in the figure below. Calculate the electric field at a point midway between the two charges on the x-axis. (Let q1 = 2.00 μC, q2 = 2.00 μC,  and q3 = −3.50 μC.) Image: Three charged particles lie in the x y-coordinate plane at the vertices of an equilateral triangle with side length 0.500 m. Positive charge q2 is at the origin. Positive charge q1 is in the first...

Three +3.0-μC point charges are at the three corners of a square of side 0.50 m....

Three +3.0-μC point charges are at the three corners of a square of side 0.50 m. The last corner is occupied by a -3.0-μC charge. Find the magnitude of the electric field at the center of the square. (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

Point charges q1=+2.00μC and q2=−2.00μC are placed at adjacent corners of a square for which the...

Point charges q1=+2.00μC and q2=−2.00μC are placed at adjacent corners of a square for which the length of each side is 3.50 cm . Point a is at the center of the square, and point b is at the empty corner closest to q2. Take the electric potential to be zero at a distance far from both charges. A point charge q3 = -5.00 μC moves from point a to point b. How much work is done on q3 by...

Three +3.0 μC point charges are at the three corners of a square of side 0.50...

Three +3.0 μC point charges are at the three corners of a square of side 0.50 m. The remaining corner is occupied by a negative -3.0 μC charge. Find the magnitude of the electric field at the center of the square. (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

Three charges are at the corners of an equilateral triangle, as shown in the figure below....

Three charges are at the corners of an equilateral triangle, as shown in the figure below. Calculate the electric field at a point midway between the two charges on the x-axis. (Let Let q1 = 7.00 μC, q2 = 4.50 μC, and q3 = −3.00 μC. magnitude =? (N/C) direction = ? (below the x-axis)

Identical +0.96 micro-Coulomb charges are fixed to adjacent corners of a square. What charge (magnitude and...

Identical +0.96 micro-Coulomb charges are fixed to adjacent corners of a square. What charge (magnitude and algebraic sign) should be fixed to one of the empty corners, so that the total electric potential at the remaining empty corner is 0 V?