Calculate the wavelengths of the following objects: (nm) a muon (a subatomic particle with a mass...

Calculate the wavelengths of the following objects in nm a) a muon (a subatomic particle with...

Calculate the wavelengths of the following objects in nm a) a muon (a subatomic particle with a mass of 1.884 × 10–25 g) traveling at 310.0 m/s b) an electron (me = 9.10939 × 10–28 g) moving at 3.80 × 106 m/s in an electron microscope c) an 75.0 kg athlete running a "4-minute mile" (i.e. 4.00 min/mile) d) Earth (mass = 6.20 × 1027 g) moving through space at 3.00 × 104 m/s

Calculate the wavelengths of the following objects: Part 1 a muon (a subatomic particle with a...

Calculate the wavelengths of the following objects: Part 1 a muon (a subatomic particle with a mass of 1.884 × 10–25 g) traveling at 330.0 m/s 10.66 nm Part 2 an electron (me = 9.10939 × 10–28 g) moving at 3.85 × 106 m/s in an electron microscope nm Part 3 an 75.0 kg athlete running a "4-minute mile" (i.e. 4.00 min/mile) x 10 nm Part 4 Earth (mass = 6.10 × 1027 g) moving through space at 2.80 ×...

1 = an 75.0 kg athlete running a "4-minute mile" (i.e. 4.00 min/mile) 2 = Earth...

1 = an 75.0 kg athlete running a "4-minute mile" (i.e. 4.00 min/mile) 2 = Earth (mass = 6.00 × 1027 g) moving through space at 3.10 × 104 m/s 3. The work function (Φ) for a metal is 6.20×10-19 J. What is the longest wavelength of electromagnetic radiation that can eject an electron from the surface of a piece of the metal?

A muon is a type of unstable subatomic particle. When high-speed particles from outer space (sometimes...

A muon is a type of unstable subatomic particle. When high-speed particles from outer space (sometimes called "cosmic rays") collide with atoms in the upper atmosphere, they can create muons which travel toward the Earth. Suppose a muon created in the atmosphere travels at a speed of 0.941c toward the Earth's surface for a distance of 3.48 km, as measured by a stationary observer on Earth, before decaying into other particles. (a) As measured by the stationary observer on Earth,...

Just as light waves have particle behavior, a moving particle has a wave nature. The faster...

Just as light waves have particle behavior, a moving particle has a wave nature. The faster the particle is moving, the higher its kinetic energy and the shorter its wavelength. The wavelength, λ, of a particle of mass m, and moving at velocity v, is given by the de Broglie relation λ=hmv where h=6.626×10−34 J⋅s is Planck's constant. This formula applies to all objects, regardless of size, but the de Broglie wavelength of macro objects is miniscule compared to their...

Calculate the magnitude of the linear momentum for the following cases: (a) a proton with mass...

Calculate the magnitude of the linear momentum for the following cases: (a) a proton with mass equal to 1.67 ×1027 kg, moving with a speed of 5.00 ×106m/s; (b) a 15.0 g bullet moving with a speed of 300 m/s; (c) a 75.0 kg sprinter running with a speed of 10.0 m/s; (d) the Earth (mass =5.98×1024 kg) moving with an orbital speed equal to 2.98×104 m/s.

Calculate the magnitude of the linear momentum for the following cases. (a) a proton with mass...

Calculate the magnitude of the linear momentum for the following cases. (a) a proton with mass 1.67 10-27 kg, moving with a speed of 4.35 106 m/s kg · m/s (b) a 16.0-g bullet moving with a speed of 385 m/s kg · m/s (c) a 79.0-kg sprinter running with a speed of 11.0 m/s kg · m/s (d) the Earth (mass = 5.98 1024 kg) moving with an orbital speed equal to 2.98 104 m/s. kg · m/s

Calculate the magnitude of the linear momentum for the following cases (a) a proton with mass...

Calculate the magnitude of the linear momentum for the following cases (a) a proton with mass 1.67  10-27 kg, moving with a speed of 4.60  106 m/s ____________kg · m/s (b) a 18.0-g bullet moving with a speed of 260 m/s ____________ kg · m/s (c) a 74.0-kg sprinter running with a speed of 12.5 m/s ____________kg · m/s (d) the Earth (mass = 5.98  1024 kg) moving with an orbital speed equal to 2.98  104 m/s. ____________kg · m/s

Calculate the magnitude of the linear momentum for the following cases. (a) a proton with mass...

Calculate the magnitude of the linear momentum for the following cases. (a) a proton with mass 1.67 10-27 kg, moving with a speed of 4.30 106 m/s kg · m/s (b) a 13.0-g bullet moving with a speed of 335 m/s kg · m/s (c) a 70.0-kg sprinter running with a speed of 10.0 m/s kg · m/s (d) the Earth (mass = 5.98 1024 kg) moving with an orbital speed equal to 2.98 104 m/s. kg · m/s

Calculate the magnitude of the linear momentum for the following cases. (a) a proton with mass...

Calculate the magnitude of the linear momentum for the following cases. (a) a proton with mass 1.67  10-27 kg, moving with a speed of 4.85  106 m/s kg · m/s (b) a 17.5-g bullet moving with a speed of 330 m/s kg · m/s (c) a 74.0-kg sprinter running with a speed of 10.5 m/s kg · m/s (d) the Earth (mass = 5.98  1024 kg) moving with an orbital speed equal to 2.98  104 m/s. kg · m/s