Positive loads of 1 μC are placed in the corners of the square, the edge of...

Four equal +6.00-μC point charges are placed at the corners of a square 2.00 m on...

Four equal +6.00-μC point charges are placed at the corners of a square 2.00 m on each side. (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2). Show your work. a) What is the electric potential (relative to infinity) due to these charges at the center of this square? b) What is the magnitude of the electric field due to these charges at the center of the square? Please show work and a pic for reference THNKS

Consider a square which is 1.0 m on a side. Charges are placed at the corners...

Consider a square which is 1.0 m on a side. Charges are placed at the corners of the square as follows: +4.0 μC at (0, 0); +4.0 μC at (1, 1); +3.0 μC at (1, 0); -3.0 μC at (0, 1). What is the magnitude of the electric field at the square's center?

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...

Consider a square of side r = 4.60 cm with two q = +9.00 μC charges...

Consider a square of side r = 4.60 cm with two q = +9.00 μC charges at adjacent corners of the square and two p = −3.00 μC charges at the other corners. a.)Find the electric field at the center of the square. Enter a positive value if the electric field is straight down and enter a negative value if the electric field is straight up. b.)Find the potential at the center of the square.

2a) Three electrons are placed on corners of a square with sides of length 14 cm....

2a) Three electrons are placed on corners of a square with sides of length 14 cm. Calculate the electric potential at the center of the square. b) Calculate the electric potential energy of two +7.1 x 10-6 C charges separated by 0.13 m. c) A 1.5 V battery contains 950 J of energy. Calculate how long it would take for this battery to completely drain if it was wired to a 9 ohm resistor. d) A -3.1 C charge moving...

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...

Consider a square which is 1.0 m on a side. Charges are placed at the corners...

Consider a square which is 1.0 m on a side. Charges are placed at the corners of the square as follows: +4.0 μC at (0, 0); +4.0 μC at (1, 1); +3.0 μC at (1, 0); -3.0 μC at (0, 1). What is the magnitude of the electric force on the +4.0 μC at (1, 1)? 0.17 N 0.36 N 0.288 N 0.21 N

Four point charges are located on the corners of the square with the side of 40cm....

Four point charges are located on the corners of the square with the side of 40cm. Three charges are 1 μC and one is -1 μ C. Find the electric potential at the center of the square (Assume that the potential at infinity is zero)

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 +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)