For the energies of 0.5, 1.0 and 1.5 MeV for an electron, provide a graphical comparison...

Particle accelerators can be used to produce alphas with kinetic energies of 25 MeV. What is...

Particle accelerators can be used to produce alphas with kinetic energies of 25 MeV. What is the error in calculating the momentum with the classical equation as compared to the relativistic equation? Express you answer in percent.

Particle accelerators can be used to produce alphas with kinetic energies of 25 MeV. What is...

Particle accelerators can be used to produce alphas with kinetic energies of 25 MeV. What is the error in calculating the momentum with the classical equation as compared to the relativistic equation? Express you answer in percent.

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 electron and positron (anti-electron) has rest energy 0.5 MeV. The two electron and positron traveling...

An electron and positron (anti-electron) has rest energy 0.5 MeV. The two electron and positron traveling in opposite direction at a speed of 0.99999*ccollide to form a new particle with a huge mass in the lab. A) What is the total energy of the two particles?   B) What is their Kinetic energy at that speed? C) What is the momentum of the two particles? D) What is the rest mass of the new particle discovered?

Determine the wavelength associated with an electron having kinetic energy equal to 0.988 MeV. Electron mass...

Determine the wavelength associated with an electron having kinetic energy equal to 0.988 MeV. Electron mass is me=9x10-31 kg, speed of light is 3x108 m/s, 1 eV= 1.6x10-19 J, h=6.6x10-34 J.s, you must apply relativistic correction for mass.

A particle of rest mass energy 18 MeV decays from rest into an electron. (a) Assuming...

A particle of rest mass energy 18 MeV decays from rest into an electron. (a) Assuming that all the lost mass is converted into the electron’s kinetic energy, find ? for the electron. (b) What is the electron’s velocity? Please show all steps and equations used

An electron has a kinetic energy K of 1 MeV and is incident on a proton...

An electron has a kinetic energy K of 1 MeV and is incident on a proton at rest in the laboratory. Calculate the speed of the CMS frame (The centre of mass, or centre of momentum, (CMS) frame is that in which the sum of the momenta (i.e., the total momentum) of all particles is zero) moving relative to the laboratory. (a) Express the initial energies Ee, Ep and initial momenta pe, pp of the electron and proton respectively (with...

A electron is accelerated to a kinetic energy of 100 MeV at the end of a...

A electron is accelerated to a kinetic energy of 100 MeV at the end of a linac and then drifts 1.45 m to a target in the laboratory a) What is the distance from the end of the linac to the target in the rest frame of the electron? b) As measured in the laboratory, what is the velocity of the electron and how much time does it take for the electron to hit the target after it exits the...

An electron is accelerated inside a parallel plate capacitor. The electron leaves the negative plate with...

An electron is accelerated inside a parallel plate capacitor. The electron leaves the negative plate with a negligible initial velocity and then after the acceleration it hits the positive plate with a final velocity ?. The distance between the plates is 19.0 cm, and the voltage difference is 113 kV. a) Determine the final velocity ? of the electron using classical mechanics. (The rest mass of the electron is 9.11×10-31kg, the rest energy of the electron is 511 keV.) b)...

A non-relativistic electron with mass m accelerates through a potential difference V that is in volts....

A non-relativistic electron with mass m accelerates through a potential difference V that is in volts. a. What is the relationship between the kinetic energy and the momentum of the electron? (Hint: Use your classical mechanics knowledge) b. Use the above relation and the conservation of energy to derive the de Broglie wavelength ? = √ ℎ2 2??? . c. Use the above expression to find the de Broglie wavelength of a proton that has been accelerated from rest through...