Two bodies, masses m1 and m2, attract each other with force F. If one of the...

Newton's Law of Gravitation states that two bodies with masses M M and N N attract...

Newton's Law of Gravitation states that two bodies with masses M M and N N attract each other with a force F=GMNr2, F = G M N r 2 , where r r is the distance between the bodies and G G is the gravitational constant. Use Newton's Law of Gravitation to compute the work (in J) required to launch a 1000-kg satellite vertically to an orbit 1000 km high. You may assume that Earth's mass is 5.98×1024kg 5.98 ×...

Two objects attract each other gravitationally with a force of 2.9×10−10 N when they are 0.60...

Two objects attract each other gravitationally with a force of 2.9×10−10 N when they are 0.60 m apart. Their total mass is 4.8 kg . Find their individual masses. M1,M2=?,?

Two charges, q1 and q2, are located a distance d apart and the each charge exerts...

Two charges, q1 and q2, are located a distance d apart and the each charge exerts on the other is F. Charge q1 is doubled and charge q2 is doubled and the separation between the charges is increased to 4d. The new force each charge exerts on the other is _______. a) 8F b) 2F c) F/8 d) 4F e) F/4 f) F/2

12. [2pt] An Atwood Machine consists of two masses m1 and m2 attached to each other...

12. [2pt] An Atwood Machine consists of two masses m1 and m2 attached to each other by a single massless string passing over a cylindrical pulley of mass M without slipping. The masses are released from rest, and allowed to accelerate until each has moved a distance h = 1.6 m. Assuming that upwards is positive, rank the velocity of m2 (from most negative to most positive) at this moment for the following cases: Case A: m1 = 11 kg,...

Two isolated masses, M1 = 2.5 kg and M2 = 619.0 kg are initially at rest,...

Two isolated masses, M1 = 2.5 kg and M2 = 619.0 kg are initially at rest, a distance d= 146.0 cm apart. Their gravitational attraction is the only force acting. Calculate the time it takes for M1 to move from that distance to 144.0 cm from M2. Assume that M2 does not move and that the force is constant over that small distance, and equal to that at 145.0 cm. Find the speed of M1 when d = 144.0 cm....

Two masses, m1 = 4 kg and m2 = 6 kg are connected with a rope...

Two masses, m1 = 4 kg and m2 = 6 kg are connected with a rope and pulled with a horizontal force F=80 N along a rough floor with a kinetics friction coefficient µκ=0.2 (Assume that g = 10 ms-2). the acceleration (in ms-2) is:

Two masses, m1=3 kg and m2=2 kg are on a horizontal surface and are connected together...

Two masses, m1=3 kg and m2=2 kg are on a horizontal surface and are connected together via a massless rope. An external force F pulls on m1 at an angle q=30° from the horizontal, as shown in the Figure 2 below. There is friction between m2 and the surface, with coefficients of friction ms=0.4 and mk=0.3, however the friction between m1 and the surface is negligibly small. What is the minimum value of F such that the masses will begin...

1. The same force at different times on two masses m1 is given an acceleration of...

1. The same force at different times on two masses m1 is given an acceleration of 4m/s2 and m2 is given an acceleration of 1m/s2. (a)What is the ratio of the masses , m2/m1 (b) suppose the two masses are combined an the same force is acted on the combination . what is its acceleration. 2. A 5g bullet is accelerated to 300m/s s down a 72cm gun barrel . Assuming a uniform acceleration. what is the net force on...

Two small charged objects attract each other with a force F when separated by a distance...

Two small charged objects attract each other with a force F when separated by a distance d/2. If the charge on each object is reduced to one-fourth of its original value and the distance between them is reduced to d/4 the force in the second case is related the force in the first case by : " I want a solution with explanation "

#1) a) Find the force of gravity between two uniform spheres as they touch each other....

#1) a) Find the force of gravity between two uniform spheres as they touch each other. Each sphere has a mass of m = 48 kg and a radius of r = 0.7 m. (Enter the magnitude in newtons.) b) What is the force of gravity between them when they stand (surface to surface) 6 m from each other? (Enter the magnitude in newtons.) #2) Two objects of masses m1 = 740 kg and m2 = 280 kg are placed...