Initially, identical point charges (+12 UC) are placed at the corners of an equilateral triangle with...
identical, positive +4.3 uc charges are placed at the corners of an equilateral triangle whose center is at the origin. one charge is placed at (x=0.00m, y=0.50m). the other two charges are placed at (x=0.433m and y= -0.25m) and (x=-0.433m, -0.25m) . How much work is required to assemble the 3 charges described in this problem?
3 identical, positive +4.3 uc charges are placed at the corners of an equilateral triangle whose center is at the origin. one charge is placed at (x=0.00m, y=0.50m). the other two charges are placed at (x=0.433m and y= -0.25m) and (x=-0.433m, -0.25m) what is the electric field at the origin x=0.00, y=0.00m?
Two identical positive point charges (q1 = q2 = +2.00 nC) are placed at the bottom two vertices of an equilateral triangle of edge length 5.00 cm. One negative point charge (q3= -3.00 nC) is placed at the apex. (a) Calculate the electrical potential produced by the combination of all three point charges together at the midpoint of the base of the triangle. (Remember that each angle in an equilateral triangle is 60 degrees.) (Answer: 816 V) (b) Calculate the...
Three charges are placed at the corner of an equilateral triangle. The bottom two corners each have a +1nC charge. Toe top of the triangle contains a -1nJ charge. The top of the triangle points in the +y direction and the sides are 10 cm long. What is the force felt by the negative charge?
Three charges are placed at the corners of an equilateral triangle, as shown in figure (18.43). The length of each side of the triangle is 1m. Determine the electric potential at the midpoint of each side.
10. Three point-like charges are placed at the corners of an equilateral triangle as shown in the figure, a 48.0 cm. Find the magnitude of the electric force exerted on the charge qs.Let qi -2.80 uC, q22.50 uC, and q-3.20 uC IN q3 q1 42
Three point charges are located at the corners of an equilateral triangle, whose side l = 0.5 m. The charges have magnitude -7.00 μC, 2.00 μC and 2.00 μC respectively. (a) Calculate the total electric potential energy of these charges. (b) How much work must be done to move the 2.00 μC charge to infinity, leaving the other two charges in place? (d) Find the (net) electric field at the midpoint between the 2.00 μC and -2.00 μC charges.
Three points charges are placed in the corners of a equilateral triangle ABC with sides 2.0 m as shown in the figure. Find the electric field at the mid point (P) of side BC. (E is a vector, need magnitude and direction.) -5 HC -6 HC
10. Three point-like charges are placed at the corners of an equilateral triangle as shown in the figure, a -36.0 cm. Find the magnitude of the electric force exerted on the charge q Let q 2.30 uC, q4.00 uC, and ,4.00 HC I N 41 42
59. Charges of 3.5 uC and -7.6 uC are placed at two corners of an equilateral triangle with sides of 0.1 m. At the third corner, what is the electric field magnitude created by these two charges? (e 8.99 x 10N-m'/c) a. 1.2E+7 N/C b. 3.0E+6 N/C c. 5.5E+6 N/C d. 5.9E+6 N/C