Two small, identical particles have charges Q1 = +8.5 μC and Q2 = -18μC. The particles are conducting and are brought together so that they touch. Charge then moves between the two articles so as to make the excess charge on the two particles equal. If the particles are then separated by a distance of 50 mm, what is the magnitude of the electric force between them?
Two small, identical particles have charges Q1 = +8.5 μC and Q2 = -18μC. The particles...
Three identical metallic conducting spheres carry the following charges: q1 = +1.00 μC, q2 = +2.60 μC, and q3 = −3.20 μC. The spheres that carry the charges q1 and q2 are brought into contact. Then they are separated. After that, one of those two spheres is brought into contact with the third sphere that carries the charge q3; those two are then separated as well. a) What is the final charge on the third sphere? 2. b) How many...
In a vacuum, two particles have charges of q1 and q2, where q1 = +3 μC. They are separated by a distance of 35 cm, and particle 1 experiences an attractive force of 3.34 N. What is q2 in μC (magnitude and sign)? (k = 9.00 x 109 N.m2/C2)?
Three identical metallic conducting spheres carry the following charges: q1 = +7.8 μC, q2 = −1.4 μC, and q3 = −4.0 μC. The spheres that carry the charges q1 and q2 are brought into contact. Then they are separated. After that, one of those two spheres is brought into contact with the third sphere that carries the charge q3. What is the final charge on the third sphere?
Two point charges, Q1 = -5.6 μC and Q2 = 1.8 μC , are located between two oppositely charged parallel plates, as shown in (Figure 1). The two charges are separated by a distance of x = 0.45 m . Assume that the electric field produced by the charged plates is uniform and equal to E = 60000 N/C . Neglect the charge redistribution in plates. Calculate the magnitude of the net electrostatic force on Q1 and give its direction.
Identical point charges q1 and q2 each have a positive charge +6.00 μC. Charge q1 is held fixed on the x-axis at x=+0.400 m, and q2 is held fixed on the x-axis at x=−0.400 m. A small sphere has charge Q=−0.200 μC and mass 12.0 g. The sphere is initially very far from the origin. It is released from rest and moves along the y-axis toward the origin. (a) As the sphere moves from very large y to y=0, how...
Calculate the electric potential at the midpoint between two charges, q1 = 1.0 μC and q2 = -1.0 μC, separated by a distance of 10.0 mm.
Two tiny conducting spheres are identical and carry charges of -17.3 μC and +72.4 μC. They are separated by a distance of 3.46 cm. (a) What is the magnitude of the force that each sphere experiences? (b) The spheres are brought into contact and then separated to a distance of 3.46 cm. Determine the magnitude of the force that each sphere now experiences.
Two tiny particles having charges +20.0 μC and -8.00 μC are separated by a distance of 20.0 cm. What are the magnitude and direction of electric field midway between these two charges? (k = 1/4πε0 = 9.0 × 109 N • m2/C2). I know that q1 and q2 become 20*10^-6 and 8*10^-6. QUESTION: why is it 10^-6
In a vacuum, two particles have charges of q1 and q2, where q1 = +3.8 µC. They are separated by a distance of 0.24 m, and particle 1 experiences an attractive force of 3.7 N. What is q2 (magnitude and sign)?
In a vacuum, two particles have charges of q1 and q2, where q1 = +3.8 µC. They are separated by a distance of 0.20 m, and particle 1 experiences an attractive force of 3.5 N. What is q2 (magnitude and sign)? C