Find the volume common to two spheres, each with radius r, if the center of one...

Two small insulating spheres with radius 6.00×10−2 mm are separated by a large center-to-center distance of...

Two small insulating spheres with radius 6.00×10−2 mm are separated by a large center-to-center distance of 0.460 mm . One sphere is negatively charged, with net charge -1.00 μCμC , and the other sphere is positively charged, with net charge 3.30 μCμC . The charge is uniformly distributed within the volume of each sphere. a) What is the magnitude EE of the electric field midway between the spheres? Take the permittivity of free space to be ϵ0ϵ0= 8.85×10−12 C2/(N⋅m2)C2/(N⋅m2) .

Two conducting spheres, one of radius 0.020 m. and the other of radius 0.170 m., each...

Two conducting spheres, one of radius 0.020 m. and the other of radius 0.170 m., each have a charge 7.00E-08 C. and are very far apart. If the spheres are connected by a conducting wire, find the final potential (in volts) in each sphere.

Two metal spheres, each of radius 3.9 cm, have a center-to-center separation of 2.2 m. Sphere...

Two metal spheres, each of radius 3.9 cm, have a center-to-center separation of 2.2 m. Sphere 1 has a charge of +1.4 × 10-8 C; sphere 2 has a charge of -3.8 × 10-8 C. Assume that the separation is large enough for us to assume that the charge on each sphere is uniformly distributed (the spheres do not affect each other). With V = 0 at infinity, calculate in volts (a) the potential at the point halfway between their...

Two metal spheres, each of radius 3.7 cm, have a center-to-center separation of 2.3 m. Sphere...

Two metal spheres, each of radius 3.7 cm, have a center-to-center separation of 2.3 m. Sphere 1 has a charge of +1.1 × 10^-8 C; sphere 2 has a charge of -3.4 × 10^-8 C. Assume that the separation is large enough for us to assume that the charge on each sphere is uniformly distributed (the spheres do not affect each other). With V = 0 at infinity, calculate in volts (a) the potential at the point halfway between their...

please solve the following :- A. A sphere of radius 3 cm, carries a volume charge...

please solve the following :- A. A sphere of radius 3 cm, carries a volume charge density of 5 − ??2, where d is constant. Find the value of d so the Electric field vector is zero outside the sphere? B.Two conducting spheres of radius 10 cm each. The center-to-center distance between the two spheres is 2 meters. Each sphere carries a charge of 16μC. Find the potential in the middle between the two spheres. C. Two conducting, concentric spheres...

Two conducting spheres of Radius R1 and R2 each have an initial charges of Qi1 and...

Two conducting spheres of Radius R1 and R2 each have an initial charges of Qi1 and Qi2 respectively. The two spheres are brought together until they make contact. After they are in contact find the ratio of the charge density of sphere 1 to sphere 2. In other words, find Charge density f1/ Charge density f2

An experiment is performed in deep space with two uniform spheres, one with mass 20.0 kg...

An experiment is performed in deep space with two uniform spheres, one with mass 20.0 kg and the other with mass 108.0 kg . They have equal radii, r = 0.30 m . The spheres are released from rest with their centers a distance 40.0 m apart. They accelerate toward each other because of their mutual gravitational attraction. You can ignore all gravitational forces other than that between the two spheres. A. When their centers are a distance 28.0 m...

A sphere with radius 1 m has temperature 11°C. It lies inside a concentric sphere with...

A sphere with radius 1 m has temperature 11°C. It lies inside a concentric sphere with radius 2 m and temperature 28°C. The temperature T(r) (in °C) at a distance r (in meters) from the common center of the spheres satisfies the differential equation d2T dr2 + 2 r dT dr = 0. If we let S = dT/dr, then S satisfies a first-order differential equation. Solve it to find an expression for the temperature T(r) between the spheres. (Use...

Two titanium spheres approach each other head-on with the same speed and collide elastically. After the...

Two titanium spheres approach each other head-on with the same speed and collide elastically. After the collision, one of the spheres, whose mass is 250 g, remains at rest. (a) What is the mass (in g) of the other sphere? (b) What is the speed of the two-sphere center of mass if the initial speed of each sphere is 4.5 m/s?

There are two identical, positively charged conducting spheres fixed in space. The spheres are 32.0 cm...

There are two identical, positively charged conducting spheres fixed in space. The spheres are 32.0 cm apart (center to center) and repel each other with an electrostatic force of F1 = 0.0750 N. Then, a thin conducting wire connects the spheres, redistributing the charge on each sphere. When the wire is removed the spheres still repel but with a force of F2 = 0.100 N. Using this information, find the initial charge on each sphere, q1 and q2 if initially...