| Relativity : Relativity Special relativity
What is special relativity about?
The evolution of concepts of space and time through history
Newtonian mechanics and Maxwell’s equations
Einstein’s space-time and consequences of Einstein’s theory
Special relativity “paradoxes”
General relativity
What is general relativity about?
Conclusions and further reading suggestions Outline |
| What is relativity about? : What is relativity about? There are actually two kinds of relativity theories: special and general, both created by Einstein. Today, we will concentrate almost entirely on special relativity.
Why do we need special relativity?
Well, here at Fermilab, we accelerate particles to very nearly the speed of light, and the way things move at such high speeds is very different from what we are used to in everyday life.
Special relativity allows us to describe what happens at very high energies
Fundamentally, both special and general theories of relativity deal with the concepts of space and time
It is curious to see how our understanding of space and time evolved through history… |
| Aristotle's physics : Aristotle's physics Aristotle's views on space, time, and motion were very intuitive; they are pretty much how people "feel" about these things.
Here are Aristotle's views on space and time:
Every sensible body is by its nature somewhere. (Physics,Book 3, 205a:10)
Time is the numeration of continuous movement. (Physics, Book 4, 223b:1) Aristotle
384-322 B.C. |
| Aristotle's space and time : Aristotle's space and time There exists a Prime Mover, a
privileged being in the state of Absolute Rest
The position of everything else is
measured with three numbers
(x, y, z) with respect to the Prime Mover, who sits at (0,0,0).
The time is measured by looking at the Prime Mover's clock x y z (x,y,z) This point of view prevailed for almost 2,000 years |
| Galileo's challenge : Galileo's challenge Galileo argued that there is no such thing as "Absolute Rest". In his view:
The mechanical laws of physics are the same for every observer moving with a constant speed along a straight line (this is called "inertial observer" for short).
Galileo Galilei
1564 -1642 |
| Galileo's space and time : Galileo's space and time Every inertial observer could declare themselves "the Prime Mover", and measure the position of everything with respect to their own set of (x, y, z)
The time is still measured by looking at the Prime Mover's clock! x y z (x,y,z) x' y' (x',y',z') z' v |
| Galileo's transformations : Galileo's transformations We have two frames of reference, K and K', and K' is moving along axis y with some constant speed v.
Something happened at point A.
According to Galileo, there is no one special reference frame -- if we know where A happened in one frame, we are done! That's because: K z x K' v x' y' z' y vt y' y A Galileo transformations:
know what happened in one frame,
can tell what happened in another |
| Newton's laws of mechanics : Newton's laws of mechanics Newton's laws of mechanics are in agreement with Galileo's relativity
A body, not acted upon by any force, stays at rest or remains in uniform motion, whichever it was doing to begin with
To get an object to change its velocity, we need a force
Sir Isaac Newton
1642-1727 Force = mass x acceleration
(acceleration = change in velocity) |
| Newton’s laws are the same in all inertial frames : Newton’s laws are the same in all inertial frames We know how positions of an object transform when we go from one inertial frame of reference to another
What about velocities?
What about accelerations? velocity of an object in K
is equal to its velocity in K',
plus the velocity of K’
with respect to K = 0 as v = const Accelerations are the same
in both K and K’ frames!
So Newtonian forces will be
the same in both frames |
| The clouds start to gather… : The clouds start to gather… For more than two centuries after its inception the Newtonian view of the world ruled supreme
However, at the end of the 19th century problems started to appear
The problematic issue can be reduced to these questions:
What is light? How does it propagate? |
| Here comes Maxwell : Here comes Maxwell Maxwell brought together the knowledge of electricity and magnetism known in his day in a set of four elegant equations known as Maxwell's equations
In the process, he introduced a new concept: electromagnetic waves, and found that they traveled at the speed of light
Light is an electromagnetic phenomenon!
James C. Maxwell
1831-1879 |
| Electromagnetic waves : Electromagnetic waves electric field magnetic field |
| Waves in general : Waves in general The waves we are all familiar with require something to propagate in
What about light?
The most natural assumption would be that it requires a medium, too! Sound waves are compressions
of air (water, etc.) Spring compressions in a slinky |
| Aether : Aether This mysterious medium for light was called aether
What would its properties be?
We see light from distant starts, so aether must
permeate the whole universe
Must be very tenuous, or else the friction would
have stopped the Earth long ago
Michelson and Morley attempted to detect aether by measuring the speed of light in two different directions: “upwind” and “downwind” with respect to aether. Aether would be like a ghostly wind blowing through the Universe! |
| Michelson-Morley experiment : Michelson-Morley experiment Michelson and Morley used a very sensitive interferometer to detect the difference in the speed of light depending on the direction in which it travels.
NO such dependence was found!
So NO aether? Or an error in the measurements? |
| Another problem : Another problem Maxwell's equations introduce the speed of light, c
But they don't say with respect to what this velocity is to be measured!
So what can we conclude?
That light must move at speed c in all reference frames?
But this contradicts Newtonian mechanics! |
| Houston, we've got a problem… : Houston, we've got a problem… If electromagnetism is governed by the same rules as Newtonian mechanics, the “addition of velocities” rule should also apply.
So if USS Enterprise is moving towards the Borg cube with the speed of light, c, and fires a photon torpedo (moving with speed c), the Borg should see the torpedo flying towards them with the speed of 2c? c c But what if uy’ = c and v = c? |
| Maybe that’s fine? : Maybe that’s fine? Suppose that addition of velocities does work for light, too. Then imagine the following experiment:
If the car is moving with speed v, and light from the rear of the car is moving with speed c, we should measure speed of light = v - c.
Then if we know c (and we do from other experiments), we should derive v.
Numerous experiments tried to measure the speed of Earth based on this general idea -- with NO results whatsoever!!! Speed of light seemed always to be the same! v I think the speed of light is v-c! |
| What do we know so far? : What do we know so far? Newton's mechanics based on Galileo's relativity
All laws of mechanics are the same in different inertial reference frames (frames moving with a constant speed along a straight line relative to one another)
Maxwell's electrodynamics
There is a fundamental constant of nature, the speed of light (c) that is always the same
The fact that there is such a constant is inconsistent with Newton’s mechanics! |
| Einstein's choices : Einstein's choices Einstein was faced with the following choices:
Maxwell's equations are wrong. The right ones would be consistent with Galileo's relativity
That's unlikely. Maxwell's theory has been so well confirmed by numerous experiments!
Galileo's relativity was wrong when applied to electromagnetic phenomena. There was a special reference frame for light.
This was more likely, but it assumed light was like any other waves and required a medium for propagation. That medium was not found!
There is a relativity principle for both mechanical and electromagnetic phenomena, but it's not Galileo's relativity.
|
| Einstein's relativity postulates : Einstein's relativity postulates It required the genius and the courage of Einstein to accept the third alternative. His special relativity is based on two postulates:
All laws of nature are the same in all inertial frames
This is really Galileo's relativity
The speed of light is independent of the motion of its source
This simple statement requires a truly radical re-thinking about the nature of space and time! Albert Einstein
1879-1955 |
| What's so radical about it? : What's so radical about it? It was Galileo who finished off the concept of Absolute Space.
Einstein added that there is no Absolute Time, either.
Simultaneity is relative!
From the point of view of
Jack, lightning struck both
train cars at the same time From the point of view of
John, lightning struck first car
A and then car B |
| Space-time : Space-time There are no such things as "space" and "time", there is only four-dimensional space-time!
How does one visualize such a thing? time space It's hard, so people usually
imagine a three-dimensional
"space" with one coordinate
being the time coordinate
this is called a space-time diagram world line event |
| Some consequences: time dilation : Some consequences: time dilation The time dilation formula can be shown to result from the fundamental postulates by considering a light clock.
Ticks every time a light pulse is reflected back to the lower mirror tock! Stationary clock: Moving clock: |
| What does this mean? :
Time in a moving system slows down comparing to a stationary system!
E.g., charged pions have a lifetime of t = 2.56 x 10-8 s, so most of them would decay after traveling ct = 8 m.
But we have no trouble transporting them by hundreds of meters!
What does this mean? No time dilation 8 m 300 m With time dilation p+ p+ |
| Some consequences: space contraction : Some consequences: space contraction Consider our light clock again, only in this case we consider the clock on its side such that the motion of the clock pulse is parallel to the clock's velocity Stationary clock: Moving clock: |
| What does this mean? : What does this mean? An observer moving along an object will find it shorter than it would be if the observer was standing still!
So a space ship moving with 9/10 the speed of light along a lattice will find that the lattice is shorter than it was when the ship was at rest! L L' |
| More consequences : addition of velocities : Knowing now time and space behave, we can now derive how velocities transform when we go from one inertial system to another:
It is only different from our familiar law of addition of velocities by a factor of (1 + uy' v/c2) in the denominator, but what a difference that makes!
If v = c and uy' = c, then uy = 2c / (1+c2/c2) = c
Speed of light really is the same in all frames! More consequences : addition of velocities |
| Lorentz transformations : Lorentz transformations These are Lorentz transformations
They show how space and time are related for two different inertial observers in special relativity
They are reduced to Galilean transformations when v << c
Maxwell's equations are invariant under these transformations
They are really a rotation in hyperbolic space formed by space and time coordinates! |
| A comment on geometry… : A comment on geometry… It is hard for us to think of going from one inertial system to another as a hyperbolic rotation. Partly this is because we are not used to thinking in terms of pseudo-Euclidean geometry.
The familiar three-dimensional world around us is Euclidean, so it's very natural for us to imagine circles and spheres that do not change under rotations (x2 + y2 stays the same)
But space-time is pseudo-Euclidean (minus instead of plus in what stays the same under rotations).
Thus, Einstein's special theory of relativity is not about how "everything is relative" -- it's about the deepest connection between space and time, and the nature of space-time.
Our understanding of space and time was further revolutionized in General Relativity… |
| Light cone : Light cone future x ct past A B C It is very convenient to represent space-time as a diagram with one axis being space and the other, time
Because the speed of light is the upper limit for all velocities, the space time is divided into three regions by a cone called the "light cone":
Past, Future, Elsewhere
A path on this diagram is called a world line
elsewhere world line light light |
| Can we really never travel faster than light? : Can we really never travel faster than light? The second postulate (that c is the same in all frames) also means that it is the highest possible speed. Otherwise, it would always be possible to come up with a reference frame where the speed of light would be higher than the "limit".
Future x Past However, people have speculated that there may exist objects that are superluminous (always traveling faster than light). They are called tachyons.
So far, they have not been seen.
Faster-than-light travel means traveling backwards in time would be possible, which would violate causality. ct A B Hypothetical tachyon |
| Slide33 : Just say NO to time travel! |
| Traveling faster that light: a catch! : Traveling faster that light: a catch! Notice, however, that special relativity only precludes things from traveling faster than light in vacuum.
In media (e.g., water or quartz) particles can travel faster than light can in that medium.
This results in the so-called Cherenkov radiation, which is a very beautiful phenomenon widely used by physicists
BaBar experiment's DIRC:
Detector of InternallyReflected
Cherenkov Radiation |
| What would you see if you were traveling close to the speed of light? : What would you see if you were traveling close to the speed of light? Imagine you are a proton traveling along Fermilab's Tevatron at a speed close to the speed of light. What would you see?
There are several effects we need to take into account:
Lorentz space contraction and dilation of time?
Yes, but these effects will be "worked into" these two effects:
Aberration of light
Doppler shift
What is aberration of light? What is Doppler shift? Let's find out! |
| Aberration of light : Aberration of light "Aberration" is just a fancy word for "addition of velocities"
Aberration of light can be illustrated by aberration of rain
At large velocities, we start to observe a similar phenomenon with light
We just need to use the relativistic formula for addition of velocities
The net effect is that light appears to converge on a point directly opposite the moving observer Train stationary
Rain falling at 60 km/hour Train is moving at 60 km/hour
Rain appears to be falling at an angle u' |
| Doppler effect : Doppler effect The Doppler effect is the familiar frequency shift we've all heard when a fire truck with its siren on passes by
Similarly for light, in the direction of motion it appears to have a higher frequency (blueshifted). hear a higher frequency
pitch when the truck
approaches us hear a lower frequency
pitch after the truck is
past us |
| Relativistic aberration : Relativistic aberration Speed
Limit
c Here we are on a remote (desert) highway, where the speed limit is the speed of light Now we are moving at about 3/4 the speed of light. Note relativistic aberration! |
| Doppler shift and headlight effect : Doppler shift and headlight effect Now we turn on Doppler shifting, so that the desert and the sky are blueshifted ahead Now we turn on the "headlight" effect. Light is concentrated in the direction of motion, which seems brighter, while everything around appears dimmer. This is probably what a proton "sees" - just a bright spot ahead! |
| Some more cool examples… : Some more cool examples… star field at rest star field at 0.99c lattice at rest lattice at 0.99c |
| Special relativity paradoxes : Special relativity paradoxes There are numerous so-called "paradoxes" associated with special relativity. They are apparent contradictions, arising because of stubborn clinging to Galileo’s notions of unique time and space existing in a single moment in time.
One of the most famous paradoxes is the twin paradox. Let us consider it in detail. It will also help us understand how to use space-time diagrams. |
| The twin "paradox" : The twin "paradox" On their 16th birthday, Jane gets her space ship driver's license and takes off from Earth at 0.8 c. Her twin brother Joe stays home.
Jane is gone for 6 yrs her time, and Joe gets older by 6 /
The "paradox" lies in the fact that from Jane's point of view, it was Joe who traveled. Shouldn’t he be younger, then? Jane has TWO inertial
reference frames! Joe's frame Jane's frame 1-(0.8c/c)2 = 10 yrs x ct x ct |
| How does kinematics cope with relativity? : How does kinematics cope with relativity? It’s all very well to say that nothing can move faster than light, but Newtonian mechanics says that:
So if we apply more and more force to an object, we can increase its speed more and more, and nothing tells us that it can’t move faster than light!
This means that Newton’s second law must be modified in relativity. It becomes: Mass m is no longer constant! |
| Mass is not preserved anymore! : Mass is not preserved anymore! It can be shown from first principles (conservation of energy and momentum) and relativity postulates that mass becomes dependent on velocity at large speeds:
If velocity v is very small comparing to c, then this formula becomes
Such considerations led Einstein to say that mass of an object is equal to the total energy content divided by c2
m0 = rest mass kinetic energy faster means heavier! |
| The world’s most famous equation : The world’s most famous equation The equivalence of energy and mass has been confirmed by numerous experiments -- in fact, we at Fermilab test it every day! m0 m0 An electron and an anti-electron (positron) of mass m0 collide and
annihilate, and two photons, each with energy = m0c2, come out! |
| Fermilab’s accelerators : Fermilab’s accelerators |
| Relativity and anti-matter : Relativity and anti-matter Given the relativistic equations for energy, mass, and momentum, we can obtain the following relation: Note that this means that E has two solutions, one with plus and one with minus sign.
But what does negative energy means? How can anything have negative energy?
It was this kind of problem that eventually lead people to the idea of anti-matter. |
| Experimental verifications of special relativity : Experimental verifications of special relativity Special relativity has been around for almost 100 years, and has brilliantly passed numerous experimental tests
Special relativity is a "good" theory in the sense that it makes definite predictions that experimentalists are able to verify.
Things like time dilation, length contraction, equivalence of mass and energy are no longer exotic words -- they are simple tools that particle physicists use in their calculations every day.
Our Tevatron couldn't function a day if we didn't take into account special relativity!
One should remember that special relativity was not something that Einstein just came up with out of the blue -- it was based on existing experimental results. |
| Is there anything left of Newton’s laws, then? : Is there anything left of Newton’s laws, then? Einstein himself felt obliged to apologize to Newton for replacing Newton’s system with his own. He wrote in his Autobiographical notes:
However, special relativity does not make Newton’s mechanics obsolete. In our slow-moving (comparing to the speed of light) world, Newton’s mechanics is a perfect approximation to work with. Newton, forgive me. You found the only way which, in your age, was just about possible for a man of highest thought and creative power. |
| What is general relativity? : What is general relativity? General relativity is an extension of special relativity to the effects of gravity.
Why was it necessary?
The universal law of gravity says nothing about time
If m1 moved, m2 would feel the change right away
This implies the existence of some agent moving faster than light, which contradicts special relativity r m1 m2 F Newton's law of gravitation F |
| Gravity is special : Gravity is special We know there are 4 forces of nature:
Gravity, Electromagnetism, Weak & Strong Nuclear forces
Gravity is by far the weakest force,
but it is also the most obvious
Because it's universal
Gravity acts the same on all forms of matter! WHY? |
| Universality of gravity : Universality of gravity Electromagnetism:
Particles have different charges (+,-, or 0)
Like charges repel, while opposites attract
Gravitation:
All particles react in exactly the same way! |
| Equivalence principle : Einstein realized that if everything feels the same acceleration, that is equivalent to nothing feeling any acceleration at all.
Equivalence principle The equivalence principle: an observer inside a (small) enclosed laboratory cannot tell the difference between being at rest on Earth's surface or being accelerated in outer space. |
| What does this imply? :
We can think of gravity as a feature
of the background in which we live.
This background is space and time:
spacetime
What we experience as gravity is
actually the curvature of spacetime
gravity is not an actor -- it's the stage itself! What does this imply? time space |
| Visualizing spacetime curvature : Visualizing spacetime curvature We can visualize spacetime curvature by tilting the light cones
The warping of spacetime outside a gravitating body deflects trajectories toward the body
We interpret that as the force of gravity |
| Black Holes : Black Holes If gravity is very strong, light cones tilt so much that all trajectories are forced into a common point (the singularity)
That's a Black Hole
Inside the event horizon, falling into the singularity is as inevitable as moving forward in time NGC 7052: evidence for a black hole? |
| Reconciling gravity with the other forces : Reconciling gravity with the other forces The (well-) known Universe consists of:
"Matter": electrons, protons, neutrons, you
"Forces": electromagnetism, weak & strong nuclear forces, gravity
A crucial distinction:
Matter and non-gravitational forces move through spacetime
Gravity, however, IS spacetime!
|
| Incompatibility with Quantum Mechanics : Incompatibility with Quantum Mechanics This distinction becomes a full-blown incompatibility when we take into account the theory underlying all of modern physics:
You will have a lecture on QM on Apr. 20
Quantum mechanics in a nutshell: flipping a coin
An ordinary ("classical") coin is always heads or tails, even
if we don't know which
A quantum-mechanical coin is described by a vector (an arrow)
in the heads/tails plane. When we observe the coin, we only
ever see heads or tails. The arrow tells us the probability of
observing H or T. Quantum Mechanics H T H T |
| Possible solution in sight? : Possible solution in sight? A promising strategy in such a situation is to invent a completely new theory, which is both consistent with quantum mechanics and somehow includes gravity
Leading candidate at the moment: string theory
This seems to solve some technical, but not conceptual, problems.
This brings up to the cutting edge of modern physics
One day one of you may come up with a consistent theory of quantum gravity! Basic idea: if you look closely enough at any
elementary particle, it's really a vibrating loop of "string"! |
| String theory pros and cons : String theory pros and cons Pros:
An apparently consistent quantum theory of gravity
A new understanding of what happens to things that fall into black holes -- not all information is lost forever
Cons:
Spacetime has to have more than four dimensions
Maybe 10, maybe 11 -- the extra ones must be hidden somehow
We don't understand the theory completely
Hard to say anything with confidence
Hard to make testable predictions (but people do try!) |
| Conclusions : Conclusions Special relativity revolutionized our understanding of space and time
There is no "space" and "time" by themselves -- there is only four-dimensional space-time!
It describes the motion of particles close to the speed of light
No massive particles can ever exceed the speed of light
Massless particles move at the speed of light
Special relativity has been extremely well-tested by experiment.
At everyday speeds, Newton's mechanics is a good approximation to work with.
General relativity is an extension of special relativity to the effects of gravity
Reconciling gravity with quantum mechanics is one of the major goals and dreams of modern theoretical physicists |
| For further reading : For further reading H. Bondi Relativity and Common Sense (Dover, 1962)
R.P. Geroch General Relativity from A to B (University of Chicago Press, 1978)
R. Penrose The Emperor’s New Mind (Oxford University Press, 1989)
J.L. Synge Talking About Relativity (North-Holland, 1970)
K.S. Thorne Black Holes and Time Wraps (W. W. Norton, New York, 1994)
E. F. Taylor and J. A. Wheeler Spacetime Physics (W.H. Freeman, New York, 1966) -- this one is a little more technical!
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| The twin "paradox" : The twin "paradox" On their 16th birthday, Jane gets her space ship driver's license and takes off from Earth at 0.66c. Her twin brother Joe stays home.
Jane is traveling towards a distant star, located 2.67 light years away from Earth in Joe's frame, and back.
By how much will Joe and Jane have aged when they meet?
Joe: 2.67 * 2 / (0.66c) = 8 yrs
Jane: 2.67 * 1-(0.66c/c)2 / (0.66c) = 6 yrs
The "paradox" lies in the fact that from Jane's point of view, it was Joe who traveled. Shouldn’t he be younger, then? Joe's signal Jane's signal Joe's worldline Jane's worldline v = 0.66 c Jane has TWO inertial
reference frames! |