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35. Special Relativity2h 10m

35. Special Relativity

Special Vs. Galilean Relativity

Physics

35. Special Relativity

Special Vs. Galilean Relativity

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Problem 59b

Textbook Question

The half-life of a muon at rest is 1.5 μs. Muons that have been accelerated to a very high speed and are then held in a circular storage ring have a half-life of 7.5 μs. What is the total energy of a muon in the storage ring? The mass of a muon is 207 times the mass of an electron.

Verified step by step guidance

Understand the problem: The half-life of a muon increases due to time dilation, a relativistic effect. The goal is to find the total energy of the muon in the storage ring, which includes its rest energy and relativistic kinetic energy.

Relate the observed half-life to the time dilation factor (γ). The time dilation formula is:

t = γ t

₀, where

t

is the dilated half-life (7.5 μs),

t

₀ is the rest half-life (1.5 μs), and

γ

is the Lorentz factor. Solve for

γ

γ = \frac{t}{t}

₀.

Calculate the rest energy of the muon using Einstein's equation:

E

_rest=mc2. The mass of the muon is 207 times the mass of an electron, and the mass of an electron is approximately

9.11 \times 10 {-31}^{kg}

. Substitute the values to find the rest energy.

Relate the total energy to the Lorentz factor:

E

_total=γE_rest. Use the previously calculated

γ

and

E

_rest to express the total energy.

Combine the results: Substitute the values of

γ

and

E

_rest into the total energy formula to express the total energy of the muon in the storage ring. This will give the final expression for the total energy.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Half-Life

Half-life is the time required for half of a sample of a radioactive substance to decay. In the context of muons, their half-life increases when they are moving at relativistic speeds due to time dilation, a phenomenon predicted by Einstein's theory of relativity. This means that the faster a muon travels, the longer it appears to live from the perspective of an observer.

Relativistic Effects

Relativistic effects arise when objects move at speeds close to the speed of light, leading to significant changes in their physical properties. For muons in a storage ring, their increased half-life is a direct result of time dilation, which states that time passes more slowly for objects in motion compared to those at rest. This concept is crucial for understanding how the muon's behavior changes under high-speed conditions.

Total Energy of a Particle

The total energy of a particle in relativistic physics is the sum of its rest mass energy and its kinetic energy. For a muon, this can be calculated using the equation E = mc² for rest mass energy and the relativistic kinetic energy formula. In the case of the muon in the storage ring, knowing its mass and the effects of its increased half-life allows for the determination of its total energy while in motion.

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Textbook Question

We cannot use Hubble’s law to measure the distances to nearby galaxies, because their random motions are larger than the overall expansion. Indeed, the closest galaxy to us, the Andromeda Galaxy, 2.5 million light-years away, is approaching us at a speed of about 130km/s. (a) What is the shift in wavelength of the 656-nm line of hydrogen emitted from the Andromeda Galaxy, as seen by us? (b) Is this a redshift or a blueshift? (c) Ignoring the expansion, how soon will it and the Milky Way Galaxy collide?

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Textbook Question

Calculate the speed of a proton (m = 1.67 x 10^-27 kg) whose kinetic energy is exactly half its total energy.

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Textbook Question

Suppose a spacecraft of mass 17,000 kg was accelerated to 0.22c.

(a) How much kinetic energy would it have?

(b) If you used the classical formula for kinetic energy, by what percentage would you be in error?

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Textbook Question

The quantity dE/dv, the rate of increase of energy with speed, is the amount of additional energy a moving object needs per 1 m/s increase in speed. A 25,000 kg rocket is traveling at 0.90c. How much additional energy is needed to increase its speed by 1 m/s?

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Textbook Question

At what speed, as a fraction of c, is the kinetic energy of a particle twice its Newtonian value?

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Textbook Question

The sun radiates energy at the rate 3.8 x 10²⁶ W. The source of this energy is fusion, a nuclear reaction in which mass is transformed into energy. The mass of the sun is 2.0 x 10³⁰ kg. What percent is this of the sun's total mass?

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Textbook Question

The sun radiates energy at the rate 3.8 x 10²⁶ W. The source of this energy is fusion, a nuclear reaction in which mass is transformed into energy. The mass of the sun is 2.0 x 10³⁰ kg. Fusion takes place in the core of a star, where the temperature and pressure are highest. A star like the sun can sustain fusion until it has transformed about 0.10% of its total mass into energy, then fusion ceases and the star slowly dies. Estimate the sun's lifetime, giving your answer in billions of years.

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Multiple Choice

Jill can throw a ball at a speed of 80mph, consistently, on the ground. She gets into the back of a truck, which drives down the road in the

+ x -direction

direction at 30mph. Jill faces the back of the truck and throws a ball. According to Galilean relativity, what is the

x -component

component of the velocity of the ball relative to the ground?

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