In which accelerated motion , the kinetic energy of a particle remain constant ?

In vertical circular motion, the ratio of kinetic energy of a particle at highest point to that at lowest point is

During a accelerated motion of a particle

A particle of mass 10 g moves along a circle of radius 6.4 cm with a constant tangential acceleration. What is the magnitude of this acceleration. What is the magnitude of this acceleration, if the kinetic energy of the particle becomes equal to 8xx10^(-4) J by the end of the second revolution after the beginning of the motion?

A particle of mass 10 g moves along a circle of radius 64 cm with a constant tangential acceleration. What is the magnitude of this acceleration if the kinetic energy of the particle becomes equal to 8xx10^(-4)J by the end of the second revolution after the beginning of the motion ?

A charge is projected in a region of magnetic field (no other field is present). Assertion: Kinetic energy of charge particle will remain constant. Reason: Work done by magnetic force on moving charge particle is zero.

A particle of mass 10 g moves along a circle of the radius (1)/(pi) cm with a constant tangential acceleration. What is the magnitude of this acceleration ("in ms"^(-1)) if the kinetic nergy of the particle becomes equal to 8xx10^(-4)J by the end of the second revolution after the beginning of the motion? (Particle starts from rest)

Show that the kinetic energy of the particle moving in a magnetic field remains constant

Initial velocity and acceleration of a particles are as shown in the figure. Acceleration vector of particle remain constant. Then radius of curvature of path of particle :