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Kinetic energy of an object can be expressed by multiplying one half (0.5) against the object's mass, times the squared ^2 speed (or inertia) of the object.
It has no direct affect on the speed of an object. It does affect the energy content of the speeding object.
Yes. Kinetic energy is a function of both speed and mass.
speed
Does speed 'effect' the gravitational potential energy of an object? No, but gravitational potential energy can be converted into kinetic energy - so the gravitational potential energy can effect the speed. Ep = mgh Energy Potential = mass * 9.81 (gravity) * height Speed / Velocity is absent from that equation.
Kinetic energy of an object can be expressed by multiplying one half (0.5) against the object's mass, times the squared ^2 speed (or inertia) of the object.
It has no direct affect on the speed of an object. It does affect the energy content of the speeding object.
It has no direct affect on the speed of an object. It does affect the energy content of the speeding object.
Yes. Kinetic energy is a function of both speed and mass.
The kinetic energy of an object is proportional to the square of its speed.
speed
More intertia makes it so more energy is needed in order to change the speed.
Does speed 'effect' the gravitational potential energy of an object? No, but gravitational potential energy can be converted into kinetic energy - so the gravitational potential energy can effect the speed. Ep = mgh Energy Potential = mass * 9.81 (gravity) * height Speed / Velocity is absent from that equation.
Increasing the speed will increase the KINETIC energy, not the potential energy. Of course, the potential energy may eventually be converted into kinetic energy, for example if the object moves upwards.
Kinetic energy is the mass times one half the velocity squared. KE = ½mv².
E=m(c squared) This is true when: E is the energy in joule. M is the mass in kilograms. C is the speed of light in kilometers per hour.
Circular motion would change the direction of an object but would not affect the object's speed.