Find the speed of a particle whose relativistic kinetic energy is 30 % greater than the...

What is the percent difference between the classical kinetic energy, Kcl=1/2m0v^2, and the correct relativistic kinetic...

What is the percent difference between the classical kinetic energy, Kcl=1/2m0v^2, and the correct relativistic kinetic energy, K=m0c^2/?1?v2/c2 ?m0c2, at a speed of 0.20 c? Express your answer using two significant figures. K?KclK = % Part B What is the percent difference between the classical kinetic energy and the correct relativistic kinetic energy, at a speed of 0.80 c? Express your answer using two significant figures.

An object has a total energy that is 2.8 times its rest energy. Part A Part...

An object has a total energy that is 2.8 times its rest energy. Part A Part complete What is its speed? Express your answer using two significant figures. v = 0.93   c   SubmitPrevious Answers Correct Part B What is the ratio of the object’s relativistic kinetic energy to its rest energy? Express your answer using two significant figures.

Find the minimum kinetic energy needed for a 3.8×104-kgkg rocket to escape the Moon. Express your...

Find the minimum kinetic energy needed for a 3.8×104-kgkg rocket to escape the Moon. Express your answer using two significant figures. Part B Find the minimum kinetic energy needed for a 3.8×104-kgkg rocket to escape the Earth. Express your answer using two significant figures.

Consider an anti-proton (rest mass = 1.007 825 amu) whose kinetic energy is 450 MeV. •...

Consider an anti-proton (rest mass = 1.007 825 amu) whose kinetic energy is 450 MeV. • Compute the ratio v/c (particle speed divided by speed of light) using both the classical expression and the relativistic expression for kinetic energy? How much error (in %) is incurred by using the classical expression?   • Compute the magnitude of the anti-proton’s momentum using both the relativistic and classical formulas. Provide you answers in units of MeV/c.   

An object with kinetic energy K explodes into two pieces, each of which moves with twice...

An object with kinetic energy K explodes into two pieces, each of which moves with twice the speed of the original object. Find the ratio of the internal kinetic energy to the center-of-mass energy after the explosion. Express your answer using two significant figures.

(a) How much time is needed to measure the kinetic energy of an electron whose speed...

(a) How much time is needed to measure the kinetic energy of an electron whose speed is 100 m s^-1 with an uncertainty of no more than 0.1 percent? How far will the electron have travelled in this period of time? (b) Make the same calculations for a 1 g insect whose speed is the same. What do these sets of figures indicate?

A particle with a charge of 37 μC moves with a speed of 77 m/s in...

A particle with a charge of 37 μC moves with a speed of 77 m/s in the positive x direction. The magnetic field in this region of space has a component of 0.42 T in the positive y direction, and a component of 0.87 T in the positive z direction. Part A: What is the magnitude of the magnetic force on the particle? Express your answer using two significant figures. Part B: What is the direction of the magnetic force...

*Proton speed The rest energy of a proton is about 938 MeV. If its kinetic energy...

*Proton speed The rest energy of a proton is about 938 MeV. If its kinetic energy is 1071 MeV, find the proton's speed as a ratio of c to 3 significant figures.

A proton has an initial speed of 4.4×10^5 m/s . A) What potential difference is required...

A proton has an initial speed of 4.4×10^5 m/s . A) What potential difference is required to bring the proton to rest? Express your answer using two significant figures. B) What potential difference is required to reduce the initial speed of the proton by a factor of 2? Express your answer using two significant figures. C) What potential difference is required to reduce the initial kinetic energy of the proton by a factor of 2? Express your answer using two...

IP A bullet with a mass of 4.2 g and a speed of 640 m/s is...

IP A bullet with a mass of 4.2 g and a speed of 640 m/s is fired at a block of wood with a mass of 9.8×10−2 kg . The block rests on a frictionless surface, and is thin enough that the bullet passes completely through it. Immediately after the bullet exits the block, the speed of the block is 21 m/s . What is the speed of the bullet when it exits the block? Is the final kinetic energy...