In the instant of the figure, two particles move in an xy plane. Particle P1 has...

Three particles are fixed in positions on the xy plane. Particle A, with a mass of...

Three particles are fixed in positions on the xy plane. Particle A, with a mass of 6.00 g, is located at the origin. Particle B, with a mass of 12.0 g, is located in the second quadrant a distance 0.500 m from the origin at an angle of 30◦ from the x axis. Particle C has a mass of 8.00 g. The net gravitational force acting on particle A due to particles B and C is 2.77 × 10−14 N...

Two marbles (m = 0.050 kg each) moving on a table TOWARDS each other with the...

Two marbles (m = 0.050 kg each) moving on a table TOWARDS each other with the speed of 0.3 m/s collide, and start moving away from each other. a) What is the total momentum of this system before the collision? V1 = 0.3 m/s, V2 = -0.3 m/s, p1 = 0.015 kg m/s, p2 = -0.015 kg m/s, ptotal = 0 kg m/s Work: P1 = (0.05 kg)*(0.3 m/s)=0.015 N P2= (0.05 kg)*(-0.3 m/s)=-0.015 N ptotal = (0.015 N) +...

Particle 1 has a mass of m1 = 3.30 × 10-6 kg, while particle 2 has...

Particle 1 has a mass of m1 = 3.30 × 10-6 kg, while particle 2 has a mass of m2 = 6.30 × 10-6 kg. Each has the same electric charge. These particles are initially held at rest, and the two-particle system has an initial electric potential energy of 0.140 J. Suddenly, the particles are released and fly apart because of the repulsive electric force that acts on each one (see the figure). The effects of the gravitational force are...

Consider a system of two particles in the xy plane: m1 = 1.95 kg is at...

Consider a system of two particles in the xy plane: m1 = 1.95 kg is at the location r with arrow1 = (1.00î + 2.00?) m and has a velocity of (3.00î + 0.500?) m/s; m2 = 3.15 kg is at r with arrow2 = (?4.00î ? 3.00?) m and has velocity (3.00î ? 2.00?) m/s. (a) Plot these particles on a grid or graph paper. Draw their position vectors and show their velocities. (Include the center of mass of...

A system consists of two particles. The first particle has mass m1 = 2.0 kg and...

A system consists of two particles. The first particle has mass m1 = 2.0 kg and a velocity of (-5.0 i+1.0j) m/s, and the second particle has mass m2 = 1.00 kg and a velocity of (1.0i - 5.0j)    m/s. A:) What is the velocity of the center of mass of this system?   B:) what is the total momentum of this system?

Two particles are moving in the xy-plane. They move along straight lines at a constant speed....

Two particles are moving in the xy-plane. They move along straight lines at a constant speed. At time t, particle A's position is given by x = t + 4, y = 1/2t-7 and particle B's position is given by x = 18 − 2t, y = 5 − 1/3t. Find the time (i.e., the value of t) at which the distance between A and B is minimal.

Two objects that are constrained to move in the xy-plane undergo a collision. Object 1 has...

Two objects that are constrained to move in the xy-plane undergo a collision. Object 1 has mass 2.3 kg and its initial momentum just before the collision has the x- and y-components 15.1 kg⋅m/s and -6.9 kg⋅m/s, respectively. Object 2 has mass 4.7 kg and the x- and y-components of its initial momentum are 3.5 kg⋅m/s and 6.5 kg⋅m/s. Immediately after the collision the x- and y-components of object 1’s final momentum are 13.8 kg⋅m/s and 4.3 kg⋅m/s. a Calculate...

A cargo plane has two wings and each wing has an area of 34.15 m2. The...

A cargo plane has two wings and each wing has an area of 34.15 m2. The mass of the cargo plane is 9310 kg. When the plane is taking off, the speed of the air over the top of the wing v2 is 1.8 times air speed under the wing v1 (i.e. v2 = 1.8 v1). If v1 is the same as the speed of the plane, what is the minimum speed of the plane v1 to obtain enough lift...

Two particles are moving toward each other along the x axis with equal speeds. Specifically, particle...

Two particles are moving toward each other along the x axis with equal speeds. Specifically, particle 1 of mass 7 kg moves to the right at 3.87 m/s and particle 2 of mass 15 kg moves to the left at the same speed. The particles collide elastically. After the collision, the first particle moves at 90◦ to its original direction while the second particle is deflected through a smaller angle θ2 < 90◦. A) Find the final speed of particle...

In the figure, two particles, each with mass m = 0.86 kg, are fastened to each...

In the figure, two particles, each with mass m = 0.86 kg, are fastened to each other, and to a rotation axis at O, by two thin rods, each with length d = 5.4 cm and mass M = 1.2 kg. The combination rotates around the rotation axis with angular speed ω = 0.33 rad/s. Measured about O, what is the combination's (a) rotational inertia and (b) kinetic energy?