Special relativity: Difference between revisions

Albert Einstein developed his theory of special relativity by 1905, when he was a twenty-six year old clerk in the Swiss patent office. The theory accounted for the paradoxical results of certain 19th century physical experiments attempting to detect the universe's background ether, which was supposed to be the ultimate neutral background or reference point against which the entire physical universe moved. Physicists had always assumed the ether's existence, but experiments--most notably the Michaelson-Morley experiment of the 1880s--always failed to detect it. By boldly refusing to assume the possibility of an ether and theorizing laws of motion without referring to an absolute background, Einstein's simple presumption of objects' "relativity" revolutionized the fundamental view of the physical universe in that his results utterly countered humans' intuitive view of the everyday world. In particular, humans' perception of time and distance, while quite correct for everyday life, inadequately understand these intuitive ideas when high speeds are involved, and so ultimately misunderstand them fundamentally. Einstein's theory says that when speed is an appreciable fraction of light's speed time passes more slowly and length shortens in the direction of motion, and so human perception fails in a fundamental way to grasp what are thought to be the intuitive ideas of time and distance.

Einstein's Assumptions

Einstein rested his theory on two uncontroversial postulates. He presumed physical experiments performed in any room moving at any constant speed in any constant direction, i.e. in any inertial frame, must always produce the same results. Along with assuming this Principle of Galilean Relativity, Einstein assumed a second fact based on recent work published by experimental physicists Albert Michaelson and Edward Morley. The Michaelson-Morley experiment aimed to determine the speed of light relative to the background ether, which required detecting differences in light's speed depending on how it moved through that ether. Surprisingly, the experiment found that light moves with exactly the same speed all the time, regardless of the motion of the object from which the light emanates or is measured. Einstein took this result at face value and postulated that the speed of light is always exactly the same in any inertial frame.

Aside from its basis in physicists' experimental results, assuming the constancy of light's speed also does not contradict human perception in any obvious way. In everyday life we experience light's speed as invariably infinite: turn on a light switch and a room is illuminated instantaneously. A simple thought experiment, however, reveals the strangeness of light's speed:

Imagine driving a car straight down a highway at 60mph. An observer on the side of the road measures our speed at 60mph. If another car comes toward us at 50mph as measured by the observer on the side of the road, we inside our car would perceive it coming at us at ${\displaystyle \scriptstyle (60+50=110)}$mph. Both cars and the outside observer are in inertial frames. From experience, we know that speeds simply add together. Now imagine that we turn on our headlights. Designating the speed of light in the traditional manner by the symbol ${\displaystyle \scriptstyle c}$, we see the light beam travel away from us at light's constant speed ${\displaystyle \scriptstyle c}$. We might also presume that the oncoming car's driver sees our light beam traveling at ${\displaystyle \scriptstyle (c+110)}$mph because experience tells us we must add the speed of our car and the oncoming car to our light beam. Our assumption that observers always measure light's speed the same, however, means that the other car sees the light beam moving at speed ${\displaystyle \scriptstyle c}$ and that the extra 110mph makes no difference. The observer on the side of the road must also see our light beam traveling at speed ${\displaystyle \scriptstyle c}$ even though it emanates from a moving car. The cars' speeds make no difference. If both cars were traveling at half the speed of light, the oncoming car would still measure our light beam as traveling at speed ${\displaystyle \scriptstyle c}$, not ${\displaystyle \scriptstyle c+(1/2)c+(1/2)c}$ regardless of the great speed of his and our car.

Time Dilation

Consider another thought experiment. We travel in a train uniformly in one direction at speed ${\displaystyle \scriptstyle v}$ (i.e. we're in an inertial frame). An observer stands motionless on the side of the tracks watching our train car pass (i.e. he's also in an inertial frame). We shoot a light beam from a flashlight straight up at a mirror on the train car's ceiling a distance ${\displaystyle \scriptstyle y}$ from the flashlight. Inside the train we see the light beam go straight up, hit the mirror, and come straight back down, covering the distance ${\displaystyle \scriptstyle y}$ twice, which is ${\displaystyle \scriptstyle 2y}$ . Let's call the short amount of time this experiment takes ${\displaystyle \scriptstyle t}$. During time ${\displaystyle \scriptstyle t}$ the train travels a short distance.

View of the light beam's path from inside the train:

    _
    |
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    |

View of the light beam's path from outside the train:

   __
   /\
  /  \
 /    \

Now consider what the observer on the side of the tracks sees. Because the train moves, he does not see the light beam go straight up and down, but sees it climb at an angle, hit the mirror, then travel back down at the same angle to hit the flashlight which has now moved a short distance. Each leg of the light beam's journey is a distance greater than ${\displaystyle \scriptstyle y}$, so it has traveled a distance greater than the ${\displaystyle \scriptstyle 2y}$ we measured inside the train. We can easily prove this by imagining a line coming down from the mirror forming a right triangle one of whose sides is the mirror's height ${\displaystyle \scriptstyle y}$ and whose hypotenuse is 1/2 the distance traveled. By the Pythagorean Theorem, the hypotenuse must be greater than ${\displaystyle \scriptstyle y}$, so the total distance traveled must be greater from the outside observer's point of view. Let's call the total distance we saw the light beam travel ${\displaystyle \scriptstyle d}$ and the outside observer's greater distance ${\displaystyle \scriptstyle D}$. The time the experiment took for us is ${\displaystyle \scriptstyle t}$, but let's designate the time passage for the outside observer as ${\displaystyle \scriptstyle t^{\prime }}$. The light beam's speed is the same for all observers, ${\displaystyle \scriptstyle c}$.

Since ${\displaystyle \scriptstyle distance=rate\times time}$ we now have

${\displaystyle \scriptstyle d=ct}$

and

${\displaystyle \scriptstyle D=ct^{\prime }}$

Since ${\displaystyle \scriptstyle D>d}$ and ${\displaystyle \scriptstyle c}$ is constant, we must conclude that ${\displaystyle \scriptstyle t^{\prime }>t}$, that is, more time passed during the experiment from the outside observer's point of view than it did from ours. In other words, from the outside observer's point of view, time passed more slowly inside the train than it did outside the train. The Theory of Special Relativity calls this effect time dilation.

Lorentz Transformation

Time dilation specifies that time passes more slowly in an inertial frame that moves relative to our own, countering human perception of time's universally uniform passage. Time's passage, however, differs infinitesimally even well beyond the top speeds humans can achieve with the help of technology such as rocket propulsion. To calculate the magnitude of time dilation and the relativistic effect on length in the direction of motion, Special Relativity employs the Lorentz Transformation first proposed by Hendrik Antoon Lorentz.

Consider now that we are motionless with our watch in an inertial frame (the reference frame) as a car with its own clock passes by in its inertial frame (the primed frame) at velocity ${\displaystyle \scriptstyle v}$. The car's length, which we measured beforehand as ${\displaystyle \scriptstyle L}$, is measured by its driver in the car's inertial frame as ${\displaystyle \scriptstyle L^{\prime }}$. If, according to our watch, we time an interval ${\displaystyle \scriptstyle t}$ after the car passes us, we know from experience the car's clock will also have passed the same time ${\displaystyle \scriptstyle t}$. If we measure the car's length as it goes by, our common sense and measuring technique also gives us length ${\displaystyle \scriptstyle L}$. The formulas ${\displaystyle \scriptstyle t^{\prime }=t}$ and ${\displaystyle \scriptstyle L^{\prime }=L}$ follow from the Galilean Transformation.

As we have already seen, though, Special Relativity's effects elude our common sense perception, so to calculate the change in time and length we use formulas following from the Lorentz Transformation:

${\displaystyle t\prime ={\frac {t}{\sqrt {1-v^{2}/c^{2}}}}}$

and

${\displaystyle L\prime =L\times {\sqrt {(1-v^{2}/c^{2}}}}$

Generally speaking, the Lorentz and Galilean Transformations specify two different mathematical techniques for mapping one Cartesian coordinate system onto another moving (primed) Cartesian system. We only apply them here to tell us how uniform motion induces time dilation and length contraction, also called Lorentz Contraction.

References

External links

• Michael Fowler's lecture on Michaelson-Morley at the University of Virginia.
• Michael Fowler's lecture on the Lorentz Transformation at the University of Virginia.
• Michael Fowler's lecture on time dilation and length contraction.