Three point charges, A = 2.35 µC, B = 7.40 µC, and C = −3.85 µC,...

Three point charges (A =2.2 μC, B = 7.5 μC, C = -3.9 μC) are located...

Three point charges (A =2.2 μC, B = 7.5 μC, C = -3.9 μC) are located at the corners of an equilateral triangle. a. Find the direction and strength of the electric field at the location of charge A again but this time find by adding the electric field from individual charges. Compare your answer to the answer you got for problem 2. NOTE: when finding the electric field at the location of charge A you do NOT add the...

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)

Three charged particles are located at the corners of an equilateral triangle as shown in the...

Three charged particles are located at the corners of an equilateral triangle as shown in the figure below (let q = 2.80 µC, and L = 0.790 m). Calculate the total electric force on the 7.00-µC charge. magnitude N direction ° (counterclockwise from the +x axis) Three charged particles lie in the x y coordinate plane at the vertices of an equilateral triangle with side length L. Positive charge q is at the origin. A charge of 7.00 µC is...

(a) Red blood cells often become charged and can be treated as point charges. Healthy red...

(a) Red blood cells often become charged and can be treated as point charges. Healthy red blood cells are negatively charged, but unhealthy cells (due to the presence of a bacteria, for example) can become positively charged. In the figure, three red blood cells are oriented such that they are located on the corners of an equilateral triangle. The red blood cell charges are A = 2.20 pC, B = 7.10 pC, and C = ?4.30 pC. Given these charges,...

3 charges, A = 1.0 µC, B = 2.0 µC, and C = 6.0 µC, are...

3 charges, A = 1.0 µC, B = 2.0 µC, and C = 6.0 µC, are located on three vertices A, B, C of an equilateral triangle with sides 10 cm each. (a)Calculate the net force on A due to B and C (b)Calculate the net force on B due to A and C (c)Calculate the net force on C due to A and B (d)Another charge q is located at the mid point of the side BC. Calculate q...

Point charges of 28.0 µC and 43.0 µC are placed 0.500 m apart. (a) At what...

Point charges of 28.0 µC and 43.0 µC are placed 0.500 m apart. (a) At what point along the line connecting them is the electric field zero? How are the electric fields due to each charge related? How can you put the two distances in terms of one distance? m (from the smaller charge) (b) What are the magnitude and direction of the net electric field halfway between them? magnitude     N/C direction     ---Select--- toward the smaller charge toward the larger...

Three identical point charges are located at the corners of an equilateral triangle that is 0.3m...

Three identical point charges are located at the corners of an equilateral triangle that is 0.3m on each side. If each charge is +20μC, than the magnitude of the net force (in N) on one of the charges due to the other two is..

2 charges, 21.44 µC each, are located at two vertices B & C of an equilateral...

2 charges, 21.44 µC each, are located at two vertices B & C of an equilateral triangle ABC with sides 2 cm each. Another charge q is located at point A. Calculate q in micro Coulomb so that net POTENTIAL at the mid point of BC will be ZERO.

2 charges, 14.34 µC each, are located at two vertices B & C of an equilateral...

2 charges, 14.34 µC each, are located at two vertices B & C of an equilateral triangle ABC with sides 2 cm each. Another charge q is located at point A. Calculate q in micro Coulomb so that net POTENTIAL at the mid point of BC will be ZERO.

a. For point charge 5.2 µC and point charge -2.9 µC located at the same positions...

a. For point charge 5.2 µC and point charge -2.9 µC located at the same positions as in the previous question (5 m and 4 m, respectively), determine the magnitude of the net electric field E at the origin (in N/C). Your answer should be a number with two decimal places, do not include the unit. b. For point charge -1.3 µC and point charge 8 µC located at the same positions as in the previous question (5 m and...