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Time, Space Obsolete in New View of Universe
Many physicists are embracing a revolutionary, still mysterious idea called string theory. The concept rejects several familiar notions and includes the existence of 11 dimensions.
By K.C. COLE, Times Science Writer
Ever since early astronomers yanked Earth from center stage in the
solar system some 500 years ago, scientists have been pulling the rug out
from under people's basic beliefs.
"The history of physics," says Harvard physicist Andrew Strominger,
"is the history of giving up cherished ideas."
No idea has been harder to give up, however--for physicists and
laypeople alike--than everyday notions of space and time, the fundamental
"where" and "when" of the universe and everything in it.
Einstein's unsettling insights more than 80 years ago showed that
static space and fixed time were flimsy facades, thinly veiling a cosmos
where seconds and meters ooze like mud and the rubbery fabric of
space-time warps into an unseen fourth dimension. About the same time,
the new "quantum mechanical" understanding of the atom revealed that
space and time are inherently jittery and uncertain.
Now, some physicists are taking this revolutionary line of thinking
one step further: If their theories are right, in the words of Edward
Witten of the Institute for Advanced Study in Princeton, space and time
may be "doomed."
Concurs physicist Nathan Seiberg, also of the institute: "I am almost
certain that space and time are illusions. These are primitive notions
that will be replaced by something more sophisticated."
That conclusion may not affect anyone's morning commute. But it is
rocking the foundations of physics--as well as causing metaphysical
reverberations that inevitably follow major changes in our fundamental
understanding of how the universe works.
The impetus behind this tumult is an idea that has become increasingly
dominant in modern physics: string theory. According to string theory,
the most basic ingredients in the universe are no longer point-like
particles, the familiar electrons and quarks. Instead, they are
unimaginably small vibrating strings of some unknown fundamental stuff.
String theory suggests that different configurations of strings
produce different harmonic chords--just as a piano produces a sound
different from that of a flute. The vibrating string gives rise to the
particles, and the way the string vibrates determines each particle's
properties. This all takes place in a convoluted landscape of
11-dimensional space.
It is a concept so strange that even theoretical physicists struggle
to understand it. String theory offers a universe bizarre beyond
imagining: Under powerful enough magnification, every known particle in
the universe would resemble a complex origami folded out of sheets or
strings of the three familiar spatial dimensions, plus one dimension of
time, plus seven extra dimensions of space.
While string theory is far from proven, or even well formulated, its
consequences would be enormous. Among other things, it would:
* Reshape fundamental notions of space and time, energy and matter,
expanding the number of dimensions to 11.
* Give the first comprehensive list of all the ingredients that make
up the universe.
* Reveal that every tick of a clock, every barking dog, every dying
star, can be described by one master mathematical equation.
Being Involved in a 'Scientific Revolution'
Which practical fruits will flow from the new view of the universe
remain unknown. But in the past, fundamental revolutions in physics
have--against everyone's wildest expectations--flowered into everything
from cell phones to brain scans.
"I've been in physics for 35 years, and this is the first time I've
felt I'm involved in a scientific revolution," said Stanford physicist
Leonard Susskind. "In the last five or six years, I really have the
feeling we're doing something as crazy, as interesting, as new as the
revolution that Einstein wrought."
Perhaps most revolutionary of all, it appears that space and time
aren't essential ingredients of a universe ruled by strings.
To grasp the extent of the current upheaval in physics, consider what
has happened to our basic understanding of space and time over the past
hundred years.
Until the early 20th century, scientists, like laypeople, assumed that
space and time were fixed--like huge, metaphysical clocks and rulers in
the firmament. Objects that moved in this unchanging background could be
pinned down to definite positions.
"Everything was where it was when it was supposed to be, and that was
all there was to it," said Strominger. "Space-time was out there. You
could count on it."
Then, Einstein revealed that space and time were woven into a single
fabric that deforms like so much Silly Putty; indeed, it is the warping
of the fabric of space-time by massive objects that produces the force of
gravity. We perceive gravity as a "force" only because we can't directly
perceive the fourth dimension.
Because gravity affects everything, everything gets warped by its
pervasive influence--including the clocks and rulers we use to measure
time and space.
Even more unsettling, Einstein's now well-proven theories showed that
the fabric of space-time, with its three dimensions of space and one of
time, is not a passive backdrop for the events and objects in the
universe. Space-time also creates objects and events.
Imagine the universe as a performance on a stage. The stage of
space-time does not act like a static floor. It also pulls and pushes the
actors around.
Quantum mechanics introduced even more uncertainty. In the subatomic
realm, the entire concept of fixed particles in time and space fuzzes out
into an ever-shifting haze of probabilities. Trying to pin down a
subatomic particle's location or motion is like trying to put your finger
on a snowflake; the very act of measurement destroys the thing being
measured.
"That means . . . space-time is an uncertain concept, so you've lost
your firm footing," said Strominger. "And that is a deep conceptual issue
we have not yet come to grips with."
Now string theory appears to be propelling this evolution one drastic,
perhaps inevitable, step further.
Certain approaches to string theory dispense with the notion of
space-time completely. Yet, they seem to produce the same set of results
as string theories with normal space and time.
To some theorists, this strongly suggests that space and time are
superfluous. Space and time as fundamental concepts may be about to
disappear altogether--literally pulling the floor out from under physics.
"The notion of space-time is something we've cherished for thousands
of years, and it's clearly something we're going to have to give up,"
said Strominger.
Even before string theory enjoyed its recent successes, physicists
knew they would have to grapple again with the inadequacy of our
understanding of space and time. The reason is a glaring mismatch between
gravity, which rules large-scale events in the cosmos, and quantum
mechanics, which rules small-scale happenings.
Both gravity and quantum theory are well understood and have survived
decades of experimental tests. Quantum mechanics gave rise to lasers and
computers; Einstein's theory of gravity predicted everything from black
holes to the bending of light by stars, insights since proved by
observations.
The problem is, the two theories are mutually exclusive. The space and
time of quantum theory don't mesh with the space and time of Einstein's
theory of gravity, or General Relativity. In the language of gravity, the
quantum mechanical aspects of the universe turn into gobbledygook. And
vice versa.
"We can describe the world that we see and experience completely,"
said UC Santa Barbara physicist Sean Carroll, "but the explanations are
internally inconsistent."
Some Things Don't Affect Everyday Life
Until recently, physicists found it easy to sweep this unpleasantness
under the rug--in part because they didn't know how to deal with it, in
part because it doesn't make a difference in our everyday lives.
The inherently uncertain behavior of subatomic particles affects only
things as small as atoms, not everyday objects like chairs; the warping
of space and time shapes the orbits of planets, but is too diluted to
make itself felt on the scale of our own backyards.
Where the large-scale fabric of space-time gets tangled in the inner
lives of atoms, however, chaos erupts; space and time fail to make sense.
And increasingly, physicists find themselves face to face with situations
where quantum mechanics and the extreme warping of space-time collide.
For example, physicists won't be able to understand either the innards
of black holes or the origins of the universe until they come to grips
with how gravity behaves at extremely small scales. Indeed, the ultimate
laboratory for studying the collision of these two opposing realms is the
infinitely compressed dollop of space-time that gave rise to the Big
Bang.
That cataclysmic speck, physicists believe, contained everything now
in our universe, so it would have packed a huge gravitational wallop. At
the same time, it would have been small enough to behave according to
quantum mechanical laws.
Because physicists can't study the Big Bang directly, they wind back
the clock with equations and thought experiments--imagining what might
happen, for example, if time really reversed.
The results are disturbing: As the universe gets smaller and smaller,
the warping of space-time gets stronger and quantum uncertainties get
progressively larger. Finally, the uncertainty becomes larger than any
time interval that could possibly be measured. Measurement becomes
meaningless.
Time at the first moment dissolves into nonsense.
"If you ask questions about what happened at very early times," said
Harvard physicist Sidney Coleman, "and you compute the answer, the [real]
answer is: Time doesn't mean anything."
Or consider what happens inside a black hole--a region where gravity
is so strong that space-time curls in on itself, in effect, shutting out
the rest of the universe. Black holes are swirling pits of pure
space-time. And according to Einstein's theory, their enormous gravity
causes them to collapse to an infinite point of zero size--what
physicists call singularity. Is there such a nonsensical thing as
infinite density packed into zero size?
"I remember puzzling about that when I was a kid," said Gary Horowitz
of the Institute for Theoretical Physics at UC Santa Barbara. "I thought
when I went to college I would find out the answer . . . I'm still
waiting."
In the pinched-off centers of black holes, space-time appears to
simply stop. "The singularity acts like an edge," said Horowitz. "You run
into it, and it's the end. There's no time after that; there's no space
after that. But we don't think physics should end [there]. That's why
we're trying to" find new laws of physics, which will describe what
happens beyond that edge.
Black holes, said Princeton physicist John Archibald Wheeler, "[teach]
us that space can be crumpled like a piece of paper into an infinitesimal
dot, that time can be extinguished like a blown-out flame, and that the
laws of physics that we regard as 'sacred,' as immutable, are anything
but."
Space, Time May Be Doomed as Concepts
String theory has emerged as the only viable candidate to reconcile
the differences between gravity and quantum mechanics. It does so by
eliminating the notion of infinitely small particles. The loop of string
is the smallest allowable size.
"You never get to the point where the disasters happen," said Seiberg
of the Institute for Advanced Study. "String theory prevents it."
But rather than rescuing space and time, string theory only seems to
make their doom as fundamental concepts more imminent.
When they are incorporated into string theory, "space and time get
confused," said Seiberg. "It's telling us that the traditional
understanding of space and time will evaporate and there will be a more
interesting and subtle result."
Some string theorists believe that space and time somehow emerged in
the early universe out of the disorganized, 11-dimensional strings. The
strings are "shards" of space and time, said physicist Brian Greene of
Columbia University.
Imagine grains of sand on the surface of a drum. If you tap the
surface over and over at the same place, the sand falls into
patterns--like iron filings around a magnet.
Did space and time emerge in the same way, as resonant patterns of
vibrating strings?
Trying to make sense of such an idea is a struggle even for theorists.
"String theory has been giving us a lot of clues," said Strominger,
"but we haven't been able to put them together into a unified picture."
Even philosophically, the challenge of replacing space and time is
daunting. What does it mean to inhabit a spaceless, timeless universe?
Clocks and rulers not only measure hours and inches; they tell us where
we've been and where we're going.
"When we talk about space and time, we think there is something there,
and we live in it," said David Gross, director of the Institute for
Theoretical Physics. The idea that space and time might be illusions, he
said, "is very disturbing. Where are we? When are we?"
The almost unfathomable scenario of a universe without space and time
in turn calls into question the very connection between cause and effect.
If time can break down, how can one event be placed clearly "before" or
"after" another?
Hypothetically, if there is no clear difference between now and the
instant after, how can we say whether the gunshot caused death--or death
caused the gunshot?
"We normally think of causality as a basic property," said Horowitz.
"Something effects something else. But when you're getting rid of space
and time . . . are we sure that causality is going to be preserved?"
New views of time could lead to even more bizarre consequences--for
instance, more than two dimensions of time, a theory being worked on by
USC physicist Itzhak Bars, among others.
Whatever the outcome of these efforts, it's clear, said Greene, that
"space is undergoing a drastic rearrangement of its basic pieces; we will
not understand string theory until we make a major breakthrough in
notions of space and time."
If Greene and his colleagues are right, expanding the universe into 11
dimensions and looping it into strings are only the beginning. On the
horizon looms a new kind of physics, where space and time melt down
completely.
"The real change that's around the corner [is] in the way we think
about space and time," said Gross. "We haven't come to grips with what
Einstein taught us. But that's coming. And that will make the world
around us seem much stranger than any of us can imagine."
The Fabric of Space-Time
Copyright 1999 Los Angeles Times
'M' Theory Stands for Magic, Matrix, Membrane, Mother or Mystery
Unseen Dimensions Hold Theory Aloft
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