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Chapter 37: Problem 23

A clock moves along an \(x\) axis at a speed of \(0.600 \mathrm{c}\) and reads zero as it passes the origin of the axis. (a) Calculate the clock's Lorentz factor. (b) What time does the clock read as it passes \(x=180 \mathrm{~m} ?\)

Short Answer

Expert verified
(a) \( \gamma = 1.25 \), (b) Clock reads \( 0.8 \times 10^{-6} \, ext{s} \).

Step by step solution

01

Understanding the Lorentz Factor

The Lorentz factor, denoted by \( \gamma \), is a key concept in special relativity. It is defined as \( \gamma = \frac{1}{\sqrt{1-\frac{v^2}{c^2}}} \), where \( v \) is the speed of an object and \( c \) is the speed of light in vacuum, approximately \( 3 \times 10^8 \, \text{m/s} \). In this exercise, \( v = 0.600c \).
02

Calculate the Lorentz Factor

Substitute the given speed into the Lorentz factor equation:\[\gamma = \frac{1}{\sqrt{1-\left(0.600\right)^2}}\]Calculating the expression inside the square root gives:\[1-0.600^2 = 1 - 0.36 = 0.64\]Then calculate the entire Lorentz factor:\[\gamma = \frac{1}{\sqrt{0.64}} = \frac{1}{0.8} = 1.25\]
03

Understanding Time Dilation Calculation

In special relativity, the relationship between the time observed in a moving system (\( t' \)) and a stationary system is given by the formula \( t' = \frac{t}{\gamma} \). However, the clock directly gives us \( t' \) when calculating from its own frame.
04

Calculate Time at \(x = 180 \, \text{m}\)

The distance \( x = 180 \, \text{m} \) is the path covered by the clock as observed from the stationary frame. The actual time \( t \) taken in the stationary frame is \( t = \frac{x}{v} = \frac{180 \, ext{m}}{0.600c} \). Convert this: \[ t = \frac{180 \, ext{m}}{0.600 \times 3 \times 10^8 \, \text{m/s}} \approx 1.0 \times 10^{-6} \, ext{s} \]
05

Determine Clock's Reading

The time the clock reads \( t' \) is the real time it experiences, calculated by:\[ t' = \frac{t}{\gamma} = \frac{1.0 \times 10^{-6} \, \text{s}}{1.25} \approx 0.8 \times 10^{-6} \, ext{s} \]

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

The Lorentz Factor
The Lorentz factor, represented by the Greek letter \( \gamma \), is an essential concept in the realm of special relativity. This factor is crucial when observing phenomena at speeds approaching the speed of light, \( c \), which is approximately \( 3 \times 10^8 \, \text{m/s} \).

To calculate the Lorentz factor, you use the formula:
  • \( \gamma = \frac{1}{\sqrt{1-\frac{v^2}{c^2}}} \)
where \( v \) is the object's velocity.
This factor explains how time, length, and relativistic mass change for an object while moving. For instance, when \( v = 0.600c \), the Lorentz factor becomes:
  • \( \gamma = \frac{1}{\sqrt{1-(0.600)^2}} \)
Upon calculating, \( \gamma = 1.25 \).
This means that time will appear to slow down by a factor of 1.25 for the observer in motion compared to one at rest.
Time Dilation
Time dilation is a fascinating consequence of Einstein's theory of special relativity. It describes how time behaves differently for observers moving relative to one another. When you travel at significant fractions of the speed of light, time for you will slow compared to someone at rest – this is called dilated time.

The relationship between the time\( t \) in a stationary frame and \( t' \) in the moving frame is given by:
  • \( t' = \frac{t}{\gamma} \)
In this formula, \( \gamma \) is the Lorentz factor.
Let's say a clock is moving at 0.600c and reaches 180 meters in the stationary frame.
In this case:
  • The stationary observer calculates \( t \) as \( \frac{180 \, \text{m}}{0.600c} \approx 1.0 \times 10^{-6} \, \text{s} \)
  • For the moving clock, \( t' = \frac{1.0 \times 10^{-6} \, \text{s}}{1.25} \approx 0.8 \times 10^{-6} \, \text{s} \)
Thus, the clock reads a shorter time, illustrating how time dilation impacts time perception in different frames of reference.
The Speed of Light
The speed of light, \( c \), is one of the most critical constants in physics, underpinning many principles of both special and general relativity. It is precisely \( 299,792,458 \, \text{m/s} \) and is considered a universal constant.

In special relativity:
  • Nothing with mass can reach or exceed it, ensuring that travel to distant galaxies remains solely in the realm of science fiction for now.
  • It represents the ultimate speed limit in our universe, a fact that every theory in physics takes into account.
In our exercise, when the clock moves at \( 0.600c \), it means the clock is traveling at 60% of this cosmic speed limit.
Multiple predictions and equations, including those for time dilation and the Lorentz factor, are deeply rooted in this constant, reinforcing the speed of light's pivotal role in understanding the nature of time and space.

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Most popular questions from this chapter

A particle with mass \(m\) has speed \(c / 2\) relative to inertial frame S. The particle collides with an identical particle at rest relative to frame \(S\). Relative to \(S\), what is the speed of a frame \(S^{\prime}\) in which the total momentum of these particles is zero? This frame is called the center of momentum frame.

(a) How much energy is released in the explosion of a fission bomb containing \(3.0 \mathrm{~kg}\) of fissionable material? Assume that \(0.10 \%\) of the mass is converted to released energy. (b) What mass of TNT would have to explode to provide the same energy release? Assume that each mole of TNT liberates 3.4 MJ of energy on exploding. The molecular mass of TNT is \(0.227 \mathrm{~kg} / \mathrm{mol}\). (c) For the same mass of explosive, what is the ratio of the energy released in a nuclear explosion to that released in a TNT explosion?

Certain wavelengths in the light from a galaxy in the constellation Virgo are observed to be \(0.4 \%\) longer than the corresponding light from Earth sources. (a) What is the radial speed of this galaxy with respect to Earth? (b) Is the galaxy approaching on receding from Earth?

The car-in-the-garage problem. Carman has just purchased the world's longest stretch limo, which has a proper length of \(L_{c}=30.5 \mathrm{~m}\). In Fig. \(37-32 a\), it is shown parked in front of a garage with a proper length of \(L_{g}=6.00 \mathrm{~m} .\) The garage has a front door (shown open) and a back door (shown closed). The limo is obviously longer than the garage. Still, Garageman, who owns the garage and knows something about relativistic length contraction, makes a bet with Carman that the limo can fit in the garage with both doors closed. Carman, who dropped his physics course before reaching special relativity, says such a thing, even in principle, is impossible. To analyze Garageman's scheme, an \(x_{c}\) axis is attached to the limo, with \(x_{c}=0\) at the rear bumper, and an \(x_{g}\) axis is attached to the garage, with \(x_{g}=0\) at the (now open) front door. Then Carman is to drive the limo directly toward the front door at a velocity of \(0.9980 \mathrm{c}\) (which is, of course, both technically and financially impossible). Carman is stationary in the \(x_{c}\) reference frame; Garageman is stationary in the \(x_{g}\) reference frame. There are two events to consider. Event \(1:\) When the rear bumper clears the front door, the front door is closed. Let the time of this event be zero to both Carman and Garageman: \(t_{g 1}=t_{c 1}=0\). The event occurs at \(x_{c}=x_{g}=0\). Figure \(37-32 b\) shows event 1 according to the \(x_{g}\) reference frame. Event 2 : When the front bumper reaches the back door, that door opens. Figure \(37-32 c\) shows event 2 according to the \(\bar{x}_{8}\) reference frame. According to Garageman, (a) what is the length of the limo, and what are the spacetime coordinates (b) \(x_{g^{2}}\) and (c) \(t_{g 2}\) of event \(2 ?\) (d) For how long is the limo temporarily "trapped" inside the garage with both doors shut? Now consider the situation from the \(x_{c}\) reference frame, in which the garage comes racing past the limo at a velocity of \(-0.9980 c\). According to Carman, (e) what is the length of the passing garage, what are the spacetime coordinates (f) \(x_{c 2}\) and (g) \(t_{c 2}\) of event \(2,(\mathrm{~h})\) is the limo ever in the garage with both doors shut, and (i) which event occurs first? (j) Sketch events 1 and 2 as seen by Carman. (k) Are the events causally related; that is, does one of them cause the other? (I) Finally, who wins the bet?

A proton synchrotron accelerates protons to a kinetic energy of \(500 \mathrm{GeV}\). At this energy, calculate (a) the Lorentz factor, (b) the speed parameter, and (c) the magnetic field for which the proton orbit has a radius of curvature of \(750 \mathrm{~m}\).
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