A particle of mass m describes an obit r = ro eθ under the action of...

A particle of mass m moves about a circle of radius R from the origin center,...

A particle of mass m moves about a circle of radius R from the origin center, under the action of an attractive force from the coordinate point P (–R, 0) and inversely proportional to the square of the distance. Determine the work carried out by said force when the point is transferred from A (R, 0) to B (0, R).

5-7 A particle of mass m moves under the action of gravity on the surface of...

5-7 A particle of mass m moves under the action of gravity on the surface of a horizontal cylinder. a) Obtain the Lagrange motion equations for the particle. b) If the particle slides in a vertical plane having left the top of the cylinder at a very small speed, find the reaction force as a function of the position. c) At what point will the cylinder particle separate?

a particle of mass m moves in three dimension under the action of central conservative force...

a particle of mass m moves in three dimension under the action of central conservative force with potential energy v(r).find the Hamiltonian function in term of spherical polar cordinates ,and show φ,but not θ ,is ignorable .Express the quantity J2=((dθ/dt)2 +sin2 θ(dφ /dt)2) in terms of generalized momenta ,and show that it is a second constant of of the motion

A particle with a charge of −60.0 nC is placed at the center of a nonconducting...

A particle with a charge of −60.0 nC is placed at the center of a nonconducting spherical shell of inner radius 20.0 cm and outer radius 22.0 cm. The spherical shell carries charge with a uniform density of −1.04 μC/m3. A proton moves in a circular orbit just outside the spherical shell. Calculate the speed of the proton. Part 1 of 6 - Conceptualize: Draw a picture of the physical setup described in the problem statement. Your picture should look...

A particle of mass m moves in a circle of radius R at a constant speed...

A particle of mass m moves in a circle of radius R at a constant speed v as shown in the figure. The motion begins at point Q at time t = 0. Determine the angular momentum of the particle about the axis perpendicular to the page through point P as a function of time.

A particle of mass m moves under a force F = −cx^3 where c is a...

A particle of mass m moves under a force F = −cx^3 where c is a positive constant. Find the potential energy function. If the particle starts from rest at x = −a, what is its velocity when it reaches x = 0? Where in the subsequent motion does it instantaneously come to rest?

particle of mass m moves under a conservative force where the potential energy function is given...

particle of mass m moves under a conservative force where the potential energy function is given by V = (cx) / (x2 + a2 ), and where c and a are positive constants. Find the position of stable equilibrium and the period of small oscillations about it.

A particle of mass m, is under the influence of a force F given by F...

A particle of mass m, is under the influence of a force F given by F = Fo [(sin ωt)ˆi + (cos ωt) ˆj] where F0, ω are positive constants. If at t = 0 the particle is at rest at the origin, find (a) the equations of motion x (t) and y (t) of the particle, and (b) the work done by the force F from t = 0 to t = 2π/ω.

An approximate experiment expression for the radius (R) of a nucleus is R = Ro A^1/3,...

An approximate experiment expression for the radius (R) of a nucleus is R = Ro A^1/3, where Ro = 1.2 x 10^-15 m and A is the mass number of the nucleus. (a) Find the nuclear radii of atoms of the noble gases: He, Ne, Ar, Kr, Xe, and Rn. (b) Determine the density of the nuclei associated with each of these species and compare them. Does your answer surprise you?

Imagine a small satellite of mass m that describes a circular orbit. If at a point...

Imagine a small satellite of mass m that describes a circular orbit. If at a point in the orbit it receives a small radial impulse when applying its motors very briefly (ignore the loss of mass), then the orbit changes a small distance δ, such that the satellite begins to oscillate with respect to its orbit r_0, it is say r (t) = r0 + δ (t), (δ (t) ≪r0) You may recall from your mechanical course that the gravitational...