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Time Travel Research Center
© 2005 Cetin BAL - GSM:+90 05366063183 - Turkey/Denizli
TRAVERSABLE WORMHOLES: SOME IMPLICATIONS
by
Michael Clive Price
price@price.demon.co.uk
First draft, later published in Extropy.
[This paper has been published in Extropy #11, where there is an error in
one of the diagrams which implies that a wormhole in flight could travel FTL,
which is not true.]
Summary:
Since 1985 there has been much theoretical progress on traversable wormholes.
At first they were thought to enable time travel, so not taken seriously.
More recent work rules out time travel and associated paradoxes, but still
permits faster-than-light travel. This article explores some of the
implications traversable wormholes have on the expansion of civilisations
through the universe. In particular it is found each civilisation would
impose a local region of simultaneity, or empire-time, which differs from
the more natural, co-moving timeframe which astrophysicists usually use.
Distant regions of the universe and alien civilisations can be reached in
short periods of empire-time, whereupon their respective empire-time zones
fuse together. Shortly after first contact is made all expanding
civilisations connect together to form a universal time. Finally some
limitations of euclidean space are contrasted with wormhole connected non-euclidean
space.
0. INTRODUCTION
To establish an interstellar trading civilisation we need a mechanism for
travel or communication at faster-than-light (FTL) velocities. This article
considers how we may achieve this and consists of this introduction followed
by the following sections:
SUBLIGHT FUTURE, in which the problems and frustration of living in universe
without faster than light travel are outlined. These problems are expected
to be magnified by the adoption of nanotechnology.
FAILED FTL, examines other proposals for breaking the light barrier and
rejects them all.
TRAVERSABLE WORMHOLES, introduces the latest candidate for FTL
TIME TRAVEL, examines whether or not traversable wormholes imply time travel.
The latest work indicates they do not.
EXPLORING THE UNIVERSE, examines how,long it might take to reach various
places in the universe with a 1-gee drive.
EMPIRE-TIME vs CO-MOVING TIME, explores the differences between the local
time frame an expanding civilisation imposes on its surrounding and the more
conventional conception of time.
ALIENS, considers some of the problems of contacting aliens. In particular
it examines how local empire time zones fuse together, forming...
UNIVERSAL TIME, the return of a universal simultaneity, which has some of
the characteristics of Newtonian time.
BEYOND THE OBSERVABLE UNIVERSE, looks at the implications of exploring
beyond the edge of the observable universe.
OTHER USES, looks at other uses of wormholes, eg in superior computer
architectures and basement universes.
LIMITS, contrasts the pros and cons of euclidean space with some of the
alternatives
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES
1. SUBLIGHT FUTURE
Without FTL travel we can still colonise the universe at sub-light
velocities, but the resulting colonies are separated from each other by the
vastness of interstellar space. In the past trading empires have coped with
time delays on commerce routes of the order of a few years at most. This
suggests that economic zones would find it difficult to encompass more than
one star system. Travelling beyond this would require significant re-orientation
upon return, catching up with cultural changes etc. It's unlikely people
would routinely travel much beyond this and return.
Nanotechnology [12] only exacerbates the situation. We expect full- nanotech,
uploading, AIs etc to arrive before interstellar travel becomes practical.
Assume we keep the same dimensions for our bodies and brains as at the
moment. Once we are uploaded onto a decent nanotech platform our mental
speeds can be expected to exceed our present rates by the same factor as
electrical impulses exceed the speed of our neurochemical impulses - about a
million. Subjective time would speed up by this factor. Taking a couple of
subjective-years as the limit beyond which people would be reluctant to
routinely travel this defines the size of a typical trade zone / culture as
not exceeding a couple of light minutes. Even single stellar systems would
be unable to form a single culture/trade zone. The closest planet then would
seem further away than the nearest star today.
With full nanotech there will be little need to transfer matter. Trade in
the distant future is likely to consist of mostly information. Design plans
for new products, assembled on receipt. Patterns of uploaded consciousness
of intrepid travellers. Gossip and news. But with communication delays to
Alpha Centauri of the order of millions of subjective years two-way
exchanges are difficult to imagine - even when we are enjoying unlimited
life spans.
Communication and exploration would be, essentially, a one-way process. If
you had a yen to travel to the Alpha Centauri you could. Squirt your encoded
engrams down an interstellar modem and arrive decode at Alpha. Assuming the
receiving station hasn't shut in the intervening millions of years of
subjective cultural change. You could leave a copy behind as redundancy or
if you wanted to explore both regions, but I suspect many of us will not
find this completely satisfactory. The speed of light barrier would limit us
and cramp our style us much more than it does at present.
2. FAILED FTL
What stops faster than light travel? According to relativity as an objects
accelerates towards the light-speed barrier its mass increases
asymptotically, slowing its acceleration with constant thrust. Ship time
slows down, which also reduces thrust (eg for a photon driven ship the
frequency of the beam red-shifts). Both make effects make light speed an
insurmountable barrier.
Since the advent of relativity there have been a number of approaches to
travelling faster than light:
Tachyons: Faster than light particles compatible with relativity. They never
have to cross the lightspeed barrier because they are posited to be created
already travelling at over the speed of light. No general consensus on
whether they would permit the transmission of information. However none have
been detected, so things look bleak either way.
Superluminal quantum effects: EPR, quantum teleportation and all that.
Relies on transmitting information via the posited collapse of the
wavefunction. Often relies on an accompanying classical sublight signal as
well. People argue passionately above the reality of the wavefunction and
whether it collapses. Until this is settled we can't expect too much here.
No quantum superluminal laboratory effect been demonstrated either.
Spinning black holes: Things looked hopeful for a while that spinning or
charged black holes might permit travel into other regions of somewhere.
More recently people have become doubtful. It seems the passage of anything
through a black hole sets off a feedback process that crushes the traveller
to death. Also infalling radiation blueshifts to infinity [10] and fries the
traveller, if tidal forces don't shred her first.
Non-traversable Wormholes: First developed in the form of Einstein-Rosen
bridges. An Einstein-Rosen bridge connects two otherwise widely separated
regions of space. Unfortunately they are very short-lived and pinch off so
quickly that only tachyons (if they existed) could travel through them and
get out the other end without getting caught in the singularity needed to
create them. But if you could travel faster than light you wouldn't need a
wormhole- Catch-22!
For all the above reasons the conventional wisdom is that faster than light
travel is the 20th century's analog of the alchemist's dream of transmuting
lead into gold or flying to the moon. Or living for ever. They seemed
impossible dreams at the time....
3. TRAVERSABLE WORMHOLES
The prospects for FTL travel looked bleak in the mid 1980s. Then Carl Sagan
asked some theoretical physicists for plausible methods for FTL to include
in his forthcoming book, Contact. Amongst the team that worked on this
problem was Kip Thorne and his graduate students at Caltech. They turned the
problem around and asked what forms of matter are required to hold a
wormhole open permanently, so no pinch off occurs? The answer is 'exotic'
matter, a highly stressed matter, with enormous tensile strengths. The
tension or pressure of exotic matter exceeds the energy density. We have no
familiarity with such matter today, but it existed under conditions of
extraordinary pressure in the early universe. Carl Sagan published Contact
in 1985 [13], incorporating the early results from Thorne's team in the
novel. Thorne et al published their conclusions in 1988 [3], and included a
recommendation for students to read Contact as a light introduction to
traversable wormholes and exotic matter!.
Later, in 1989, Matt Visser published an article [1] showing how more
general traversable wormholes could be constructed. A wormhole could be
constructed, according to Visser, by confining exotic matter to narrow
regions to form the edges of three-dimensional volume, for example the edges
of a cube. The faces of the cube would resemble mirrors, except that the
image is of the view from the other end of the wormhole. Although there is
only one cube of material, it appears at two locations to the external
observer. The cube links two 'ends' of a wormhole together. A traveller,
avoiding the edges and crossing through a face of one of the cubes,
experiences no stresses and emerges from the corresponding face of the other
cube. The cube has no interior but merely facilitates passage from 'one'
cube to the 'other'.
The exotic nature of the edge material requires negative energy density and
tension/pressure. But the laws of physics do not forbid such materials. The
energy density of the vacuum may be negative, as is the Casimir field
between two narrow conductors. Negative pressure fields, according to
standard astrophysics, drove the expansion of the universe during its 'inflationary'
phase. Cosmic string (another astrophysical speculation) has negative
tension. The mass of negative energy the wormhole needs is just the amount
to form a black hole if it were positive, normal energy. A traversable
wormhole can be thought of as the negative energy counterpart to a black
hole, and so justifies the appellation 'white' hole. The amount of negative
energy required for a traversable wormhole scales with the linear dimensions
of the wormhole mouth. A one meter cube entrance requires a negative mass of
roughly 10^27 kg.
Wormholes can be regarded as communication channels with enormous bandwidth.
The wormhole will collapse when the amount of mass passing through it
approaches the same order as the amount of negative mass confined to its
edges. According to Shannon [16] and others [14] information has a minimum
energy of kTlog2 associated with it. For 1- meter radius cube this implies a
potential bandwidth of over 10^60 bits/sec [15]. Even very small nano-scale
wormholes have bandwidths of the order > 10^50 bits/sec. This suggests it
will usually be more economic to squirt the design of an object down a
channel rather than the object itself.
Construction of such cubes is, of course, far, far beyond our present day
abilities. With AIs and nanotech combined we expect the limits on
intelligences to be governed by physics, not biology [12]. Our brains'
processing capacity lies somewhere between 10^15 - 10^18 bit/sec. A
comparably sized nanoelectronic brain would have power of 10^32 - 10^36 bit/sec
[15]. Assuming a factor of million is lost for the speedup still leaves 8 -
12 orders of magnitude expansion in the complexity, or depth of thought, of
our brains as we switch from biology to nanotechnology. So we should not
assume construction and manipulation of the materials required will long
remain beyond the grasp of future civilisations, populated by such super-intelligences.
The remainder of the article will assume the mass production of wormholes is
economically achievable.
Wormholes enable travel from one mouth to the other. To travel to distant
parts of the universe one wormhole end stays at home and the other is carted
away, at sublight velocities, to the destination. Before we examine this
first we consider some other properties of wormholes.
4. TIME TRAVEL
Wormholes are constrained by relativity to travel at sublight speeds and are
time-dilated as per normal. Clocks placed at the mouths of a wormhole always
remain in synchronisation with each other. If I look through one end of a
wormhole and compare the near clock with the far clock they always agree.
Even if one end of the wormhole is travelling at relativistic speeds many
light years away. Einstein says moving clocks run slow. There would appear
to be a paradox here. We observe the two clocks keeping time with each other,
yet relativity says the 'distant', travelling clock is running slowly. How
do we reconcile this? Only by concluding that the distant clock has been
displaced in space and time. If a wormhole enables someone travel from Alpha
Centauri 2000 to Sol 1993 and vice versa, then no paradox because they can't
travel back to Alpha Centauri (through conventional space) and arrive before
they left (to cause a paradox).
Problems begin when the distant wormhole end turns about and returns home.
According to the twin paradox the traveller returns aged less than the stay-at-home
twin (their clocks are no longer in step). Travelling through the wormhole
from the stay-at-home end to the go- away-and-come-back end transports you
forward in time. Travelling in the reverse direction transports you back in
time. Wormholes allow time travel. This conclusion was realised soon after
the first articles on traversable wormholes were published. Depending on
your view of the plausibility of time travel this is either, if you believe
time travel possible, very exciting or, if you scoff at time travel, proof
that traversable wormhole can't exist. No general consensus emerged in the
pages of various physics journals as the subject was batted back and forth.
Elaborate and very interesting papers (by Thorne's group [7] and others)
reconciled time travel with quantum theory, whilst others (like Hawking )
proposed a Chronological Protection Conjecture, CPC, which says the Universe
Shalt Not Allow Time Travel.
One of the time travel sceptics was Matt Visser. Early in 1993 he showed
that wormholes do not enable time travel [2], by proposing physical
mechanisms that enforce CPC. Visser showed, in a peer reviewed article, the
mouths of a wormhole with an induced clock difference could not be brought
close enough together to enable a traveller to attempt violation of
causality. Quantum field and gravitational effects build up as the two ends
of a wormhole approach the critical point and either collapse the wormhole
or induce a mutual repulsion. Visser's work is not complete but it seems
swarms of virtual particles disrupt the region around a time machine just
before it would otherwise become operational.
The virtual particles around a nearly chronologically violating region are
able form closed spacelike (superluminal) loops and, via Heisenberg, to
borrow energy off themselves, becoming more virulent than usual. Traversable
wormholes are closed, or pinched off, by the energy of the virtual particles
that flow through them as they approach being time machines which prevents
the more dangerous closed timelike loops (which may cause paradoxes). For
the purposes of this article I'll adopt Visser's conclusion that the CPC
mechanism is generic and blocks all forms of time travel via wormholes, but
permits the operation of wormholes for the purpose of FTL travel.
5. EXPLORING THE UNIVERSE
Time dilation has the effect of reducing trip times for relativistic
travellers. A traveller accelerating at one-gee reaches close to the speed
of light within a few years. As it speeds up ship time dilates more and more.
Ship or journey time to various locations, at one gee, are, not allowing for
slow-down:
Destination (light years) Ship time (years)
Alpha Centauri 2.3
Centre of Milky Way 11
Andromeda Galaxy 15
Alien neighbours 19?
Edge of observable universe 24
Edge of inflationary bubble probably
[trips times are not subjectively much altered if we allow higher
accelerations for nanomachines, that can take millions of gees in their
stride [12]. Actual trip times are reduced, but increased mental speeds
compensate to make a journey of a day seem like centuries]
A space probe with a wormhole could be powered from base. The fuel is
uploaded through the wormhole from base to the in-flight ship. There would
an energetically very strong potential hill for the fuel to climb to reach
the ship. For a ship moving at relativistic speeds most of the energy of the
fuel would be lost in the climb. This suggests that the ship would be
stripped to the bare minimum, just modern rockets are.
The probe remains in contact with the home base, throughout the trip. As a
drop point approaches another wormhole plus deceleration rig would be loaded
through to detach itself from the mother craft. Deceleration would likely be
quicker and less expensive than acceleration because the daughter craft
could brake itself against interstellar/galactic gas, dust and magnetic
fields. For energy cost reasons it is not likely that transfer of colonists
would begin until deceleration is complete.
The colonists transfer through this hole, whilst the main probe continues
its outward voyage. One of the first activities of colonists would be to
secure the connections with home by increasing the wormhole capacity and
numbers. Transport of manufacturing plants, more wormholes etc would
continue until local nanotech factories become locally more competitive than
transport of finished product via wormholes. After this point the wormholes
would be increasingly used for communications rather than materials
transport.
An analogy with the cloud chamber spring to mind here. Charged particles are
tracked through cloud chambers. Each particle is invisible, but its presence
is deduced from the trail of growing droplets left behind. Similarly the
space probe is all but invisible, lost in the immensity of the dark of space.
The burgeoning colonies left behind mark its passage. The colonies send out
further wormholes probes. From a distance the whole affair would resemble a
growing 3-D snowflake.
Road, sea and air routes let commerce draw on the whole earth's resources
and the telecommunications highways keep us in contact with each other.
Wormhole connections laid down by space probes enable a space-faring
civilisation to remain a single economic entity, with all the social and
material benefits that follow. Wormholes connections enable the region
colonised to stay interconnected as civilisation expands through the
universe.
Wormholes do have one major trick up their sleeves. We have seen that
wormholes don't permit time travel. But they do exhibit some very strange
effects. Consider a colonist stepping through the home wormhole to transfer
to the landing ship. Ship time and home time are running in synchronisation.
If I wait 15 years at home after launch before stepping through then I
appear at the travelling end at the point when the probe passes Andromeda.
In crossing 2,250,000 light years of conventional space I travel 2,250,015
million years into the future as defined relative to the co-moving frame of
the universe.
6. EMPIRE-TIME vs CO-MOVING TIME At this stage it worth a digression to
explain what this means. Co- moving space-time is the space-time frame in
which the average background distribution of matter is stationary. Our
galaxy is moving relative to this background distribution. We can measure
this drift by noticing the slight shift in frequency in the cosmic microwave
background distribution. Backwards along our path it is slightly red-
shifted. Forward along our direction of motion it is slightly blue shifted.
Relativity tells us all reference frames are relative, but in truth most
astronomers think of the co-moving frame as a natural choice, or Schelling
point, to adopt, even though we are drifting with respect to it. It makes
the dynamics of the expansion of the universe much easier to calculate, for
starters. At each point in co-moving time the averaged distribution of
matter is even.
The time frame being defined by the expansion of wormholes, which I dub
empire-time, is not coincident with the co-moving time. Wormholes sent to
the Andromeda at near light speeds arrive in approx year 2,250,000 co-moving
time, but in year 15 empire-time (setting year zero at start of expansion).
Assuming once wormhole technology is developed we expand at near light
speeds then the surface of constant empire-time forms an inverted cone in co-moving
space time, with Earth at apex. [I use the language of cones to describe
what is really a sphere, but this is conventional in relativity texts,
because it lends itself to greater ease of visualisation] At any particular
moment in empire-time the entire surface of the time cone is accessible to
the wormhole traveller.
Travelling along the wormhole highways away from Earth takes you into the
future of co-moving time, but not in empire-time. Later empire-time zones
form inverted cones, like inverted dunces's hats stacked on top of each
other.
Attempts to redefine the empire-time already laid down by wormhole structure
is resisted by CPC. To redefine empire-time you would have to repopulate a
region with holes travelling at a vastly different speed than the original
colonists. The CPC mechanism says two holes disturb each other as they
approach closer than their empire-time difference times speed of light eg
two holes with an empire-time difference of a year can't approach closer
than a light year. If the holes are of greatly different size then only the
smaller hole is destroyed. Otherwise they both are violently disrupted and
destroyed.
Once the empire-time frame has been defined it becomes increasingly
difficult to change it. As the population and economy of a region grows they
increase the wormhole traffic carrying capacity of the locale. Once
established to change the relationship between co-moving and empire-time
would require the complete upheaval of the local economy and denizens.
Economic growth would breed chronological stability.
Questions about the distant co-moving future of our universe are answered
directly by travel. How quickly is the Hubble constant decaying? Would the
natural universe expand forever or re-collapse? Is the universe spatially
closed? Send out a probe at one-gee. From the above table we see that within
a century of empire-time it is reporting back on the universe at almost
inconceivable distances and futurities, answering questions about the fate
of the natural universe. If you wish you can visit the end of the universe,
and come back. "Go see the end of the universe" might be a catchy travel
company's jingo. (Actually this would only be possible in an open universe.
In a closed universe there would be a limit to how far you travel before CPC
prevented you.)
7. ALIENS Circumstantial evidence indicates alien civilisations are very few
and far flung in the universe. Frank Tipler has pointed out that the easiest
way to explore the universe is send out self-replicating space probes [11].
Within a cosmologically short period of co-moving time (ie millions of years)
we could colonise the Milky Way and the rest of the Local Group. Tipler
argues (and I agree) that the arrival of such a probe at a star system would
preclude and supersede local biological evolution. Since life on Earth has
evolved over billions of years then we can't expect (statistically speaking)
to find civilisations within our local group. Where are the aliens, asked
Fermi. Many megaparsecs away, says Tipler.
An elaboration of this argument gives grounds for believing that the nearest
aliens are currently over a 100 million light years distant. In the co-moving
frame, without wormholes, we won't make contact with them for over 100
million years. Which makes their existence an object of theoretical
speculation that can't be resolved for millions of years.
With relativistic probes and on-board wormholes, though, we can reach alien
colonised regions within decades of empire-time, no matter (almost) how far
away they are. No probe can penetrate into a region of alien colonised space.
Each civilisation defines its own empire-time that is in conflict with the
empire-time of the other. A probe from Earth flying into a alien zone not
only crosses alien space, but also crosses alien empire-time zones. As it
approaches the alien home world it passes into the alien empire-time future.
CPC forbids such travel by destroying lone wormholes that attempt to
interpenetrate each others empires. Only a full scale invasion with masses
of wormholes could ever succeed. Such an invading fleet would have to
overwhelm the native wormholes (destroy them) and impose their own empire
time on the stranded natives. Given the rates of economic growth we expect
the advantage would almost always lie with the defenders. As the invading
fleet cut deeper and deeper into the alien heartlands it find itself opposed
by later and later alien time zones, more advanced technology and greater
forces of numbers. Economic might, then as now, ensures protection. Brute
force invasion would be suicide for the invaders and their whole empire:
once defeated the invader's whole wormhole connected empire would be open to
subversion from 'aliens from tomorrow'.
A much more likely scenario would be: Contact is signalled by our leading
wormhole probes failing in the overlap of our sphere of influence with the
alien empire's sphere. Finding each other's probe colony ships would be non-trivial.
It might be easier to find the colonists than the original exploration
vessels. To push the analogy with a particle zipping through a cloud chamber,
search for the droplets, rather than the elusive particle. The easiest way
of doing this is, at the point where the relativistic wormholes are
destroyed, is to send out sub-light non-relativistic survey probes to
establish diplomatic relations. If both sides explore each other with non-
relativistic probes (relative to the co-moving frame) then their empire
times will realign themselves, over the locale of the 'neutral zone',
permitting diplomatic contact and, assuming no wars, eventual exchanges of
wormholes. The spheres of colonisation are then available to each other and
the two empire times merge.
Other expansion scenarios are possible. A well coordinated, centrally
controlled species might halt expansion at the boundary of their home galaxy
(say) for a few subjective million years, building up numbers, armaments etc.
When their technology seemed to have plateaued they resume their expansion
relying on technology and numbers to overwhelm aliens. Such a strategy is
technology dependent. If it turns out that wormholes can be booby-trapped to
explode on tampering or hostile attack such a strategy would fail.
8. UNIVERSAL TIME Barring such hostile aliens we can expect to have
contacted and be trading with alien civilisations within a few centuries or
millennia of starting our wormhole exploration of the universe. This is a
symmetrical situation. Not only will be meeting aliens within historically
short period, but they will be meeting us shortly after their expansion
begins. Consequently all the species of the universe will be linking up at
about the same stage in their development. This gives us all shared
interests and hence markets in common. We might expect each civilisation to
go through two future phase changes. First phase change is when they develop
nanotechnology and start redesigning themselves, speeding up etc. Second
phase change occurs when they link up with the rest of the universe and get
the benefits of the near- infinite economies of scale this brings.
At this point all the local empire-times have merged to form a universal
time or simultaneity surface. On a very large scale the sheet of universal
time conforms with the co-moving average. On closer inspection (ie scales of
billions of years and light years) the universal time surface reveals
conical pit-like indentations that mark the place where each civilisation
arose and stamped its own chronological footprint on the surrounding space-time
topology before merging with their neighbours. By saying the universal time
surface is indented I am revealing my co-moving prejudices. From the vantage
of point of someone from universal time it would be co-moving time that
would appear bumpy. To them civilisation birth points appear as the summits
of cones in the co-moving time surface. Universal time would be the
preferred time for discussing life, history, politics etc - everything
except prehistory before Link-Up. Absolute time, as Newton conceived of it
[18], would have finally returned. The notion of relative time frames would
be irrelevant.
Half the civilisations we meet are likely to have been around, in co- moving
terms, hundreds of millions or even billions of years before us. Gaining
access to their time zones would enable our astronomers to observe the
expansion of the universe in the distant past (although always further away
from here in space than co-moving time). The occurrence of the first
civilisation in the universe would be the limit beyond which we could not
travel.
9. BEYOND THE OBSERVABLE UNIVERSE The expansion of the universe is defined
by a parameter called Hubble's constant, which relates the distance of a far
galaxy with its velocity of recession. Beyond a certain distance the
recession velocity exceeds the speed of light. Objects beyond this are red-shifted
to infinity and are unobservable. This distances defines the edge of our
observable universe, an event horizon, and lies approximately (subject to
experimental error) 15-30 billion light years away. This is limit of the
astronomer's universe. What lies beyond is pure conjecture and is left to
cosmologists. Cosmological theories expounded over the last decade (in
particular inflationary theories) indicate that the observable universe is
just an infinitesimal speck in a greater post- inflationary bubble that
extends over distances of 10^30 light years or more, looking pretty much
everywhere as it does here. Inflationary theories differ about what lies
beyond this, although one suggestion is that naturally occurring wormholes,
inflated to astronomical dimensions, [6] may link our post-inflationary,
bubble with others, forming an infinitely large chaotic, fractal structure
[17]. Unless we link up with aliens then we may never directly observe this
since these regions will have changed greatly in the century or two of
empire-time (> 10^30 years of co-moving time) it takes to reach them.
A couple of paragraphs back I mentioned the phase change, Link-Up,
associated with linking up with the rest of the universe. It's worth while
stopping for a moment and considering what this might do to our perception
of ourselves and our place in the universe. At the moment we are the only
civilisation we know, unique and conceited. Even if civilisations are
scattered at distances of 100 million light years, in a universe of radius
10^30 light years this still yields over 10^60 alien cultures. It is
unlikely anyone could ever catalogue all the civilisations and cultures,
even if they did have a nanoelectronic brain! No single mind could encompass
all of history. We would have returned to the medieval world, surrounded by
legends of distant lands populated by mythical and fantastic creatures.
Construction of a universal map would be impossible. A trans-human traveller,
exploring the highways and byways of life, would likely never encounter
another trans-human, beyond the 'here be dragons' point. If she lost her
personal wormhole and forgot her trans-species designation code (a sixty
digit number!) she would never, ever find her way home again. None of her
descriptions of where she comes from would relate to anything anyone else
knows.
10. OTHER USES Other uses of wormholes may be where the euclidean geometry
of space is already confining us. As an example computer architectures are
cramped and hindered by speed of light limitations which are causing timing
problems, limiting chip clock speeds, I/O delays etc. Nanoscale wormholes,
with their fantastic bandwidths could be used to supplement the data buses,
conveying data from one section of a chip or computer to another, faster
than conventional transfer would allow. Or link up networks of computers for
super fast number crunching.
Initially, no doubt, the wormhole connections would supplement existing
architectures. The next logical step would be to design things for different
topologies other than the natural euclidean one. Instead of having computers
in euclidean space, linked together with wormholes, why not place them in
the wormhole, out of harms way. The technologies involved in generating
artificial inflation to expand the interiors of wormholes into basement or
baby universes are of the same orders of magnitude as creating traversable
wormholes. Construction of basement or baby universes has already been
discussed and computer-simulated in the literature [4], [8].
We have already mentioned that we expect speedup rates of a million or so
with the adoption of full nanotech. If just a factor of a thousand
translates into GDP growth and population rates then doubling times for the
economy may drop from decades to days. I don't know if these growth rates
are sustainable, even in empire-time, but they indicate that any limited
resource is likely to be at a premium, within a years / subjective millennia
of empire-time. Since the amount of natural space per civilisation is finite
economics dictates that eventually more and more of the economy will shift
over and occupy the artificial space provided by basement universes.
11. LIMITS In a sense exponential growth and euclidean space are natural
enemies. The volume enclosed by a euclidean 3-sphere only increases with the
cube of the radius. With exponential growth pressures driving expansion all
civilisations confined to euclidean space will rapidly hit technological
limitations or each other. Wormholes and associated basement universes offer
the long term prospect of escaping from this dilemma. An array of basement
universes connected by wormholes has the useful property that the volume of
space enclosed grows exponentially with distance from origin. A civilisation
driven by exponential expansion need only grow radially at a constant rate,
unlike in euclidean space where it must expand at ever faster rates.
This might seem some like subtle and obtuse piece of mathematics, but in
fact it's just a restating that a tree with continually branching twigs
eventually strangles itself (in euclidean space), whereas it could grow for
ever through a tangled array of wormholes and basement universes. A related
limitation of euclidean space is the amount of information a volume can
contain before a black hole forms. This limitation, given by the Bekenstein-Hawking
bound [], grows with the radius squared. No such limitation applies to a
space of connected basement universes. Each basement universe is shielded
from the positive energy contribution of its neighbours by the connecting (negative
energy) wormhole
12. CONCLUSION We have seen that whilst the construction of wormholes is
technically very difficult the long-term payoffs are very great. A
civilisation can expand through the universe, stamping its own chronology on
its locality, at a speed only limited by its energy resources. At the very
least the problems of construction, theoretical and practical, will exercise
the advanced intelligences of the future considerably. In the longer term
the capabilities of opened-ended infinite information processing lie before
the civilisations who solve the problem.
13. ACKNOWLEDGEMENTS I am very grateful to Robin Hanson for initially
directing my attention to the subject of information processing limits and
his subsequent help on all aspects. My thanks to all the other recipients of
the extropians (tm) mailing list for their feedback. Needless to say none of
the above share any responsibility for some of my conclusions or any of my
errors.
It has all been enormous fun.
References: [1] Matt Visser. Traversable Wormholes: Some Simple Examples.
Physical Review D v39, n10, p3182, 15-May-1989.
[2] Matt Visser. From Wormholes to Time Machines: Remarks on Hawking's
Chronology Protection Conjecture. Physical Review D v47, n2, p554. 15-Jan-1993.
[3] Morris and Thorne. Wormholes in Spacetime and Their Use for Interstellar
Travel. American Journal of Physics v56, p395 (1988)
[4] M Visser. Wormholes, Baby Universes and Causality. Physical Review D
v41, n4, p1116 (1990).
[5] S Hawking. Chronology Protection Conjecture. Physical Review D v46 n2
p603 15-July-1992.
[6] Thomas Roman. Inflating Lorentzian Wormholes. Physical Review D v47, n4,
p1370 15-Feb-1993.
[7] Thorne et al. Cauchy Problem in Spacetimes with Closed Timelike Curves.
Physical Review D v42 p1915 (1990).
[8] KA Holcomb et al. Formation of a "child" universe in an inflationary
cosmological model. Physical Review D v39, n4 15-Feb- 1989.
AD Guth, Blau and Guendelman. Dynamics of False Vacuum Bubbles. Physical
Review D v35, n4 p174 (198?).
[9] Mikheeva and Novikov. Inelastic Billiard Ball in a Spacetime with a Time
Machine. Physical Review D v47, n4 p1432 15-Feb-1993.
[10] W Israel & AE Sikkema. Nature v349 n6304 p45 (1991).
[11] FJ Tipler. Quarterly Journal of the Royal Astronomical Society v22 p279
(1981)
[12] Eric K Drexler. Engines of Creation (1986) Garden City, New York:
Anchor Press. Also Nanosystems 1991 draft
[13] Carl Sagan, Contact, pub New York: Simon & Schuster(1985)
[14] T Schneider. Energy Dissipation from Molecular Machines. Journal of
Theoretical Biology, v148, p125 (1991).
[15] T Schneider. Channel Capacity of Molecular Machines. Journal of
Theoretical Biology, v148, p83 (1991).
[16] C Shannon. Communication in the Presence of Noise. Proceedings of the
IRE (now the IEEE), v37, p10-21 (1949).
[17] Scientific American, April 1993, p10. AD Linde
[18] Isaac Newton. On the Gravity and Equilibrium of Fluids (1668?)
Translated in 'Unpublished Papers of Isaac Newton' ed AR and Marie Boas Hall
(1962)
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