Wormholes:
“It
turns out that there are very simple, exact solutions of the Einstein
field
equations which describe wormholes that have none of the above problems. If,
somehow, an advanced civilization could
construct such wormholes, they could be used as a galactic or
intergalactic
transportation system and they might also be usable for backward time
travel.”
- Michael Morris and Kip Thorne,
18A.T.
“A
wormhole is any compact region of space-time with a topologically
simple
boundary, but topologically non-trivial interior.”
- Matt Visser, 26A.T.
First
postulated as far back as
the
early
Information Age, wormholes are artifacts of space-time engineering
which
provide rapid transportation across distances that would normally
require
decades, centuries, or millennia to cross.
The Wormhole Nexus, or simply
Nexus, is the foundation of modern
galactic commerce.
Wormholes are the product of high
transapient intelligence. Indeed, it was not until after the evolution
of the
Third Singularity that the means to create such devices became
available.
Since then, each new
Singularity level has
refined or advanced the technology of wormhole creation, until in the
modern
era it is theorized that even the very minds of the gods are bound up
somehow
in structures of wormhole linked space-time.
All but
the most basic details
of
wormhole
creation are beyond the comprehension and generally beyond the interest
of
modosophont minds, but the basics of wormhole operation and usage are
readily
understandable.
Types of
Wormholes:
Theoretically
there are several
different
types of wormhole that may be created within the bounds of the laws of
physics.
While some are believed to be
employed by the highest Singularity level minds, to date only two are
in common
usage by modosophont level intelligence.
Traversable
Wormholes:
Traversable
wormholes (as their
name
implies) are mostly used to link distant points in space that would
otherwise
take years, decades, or centuries to travel between even at the speed
of light.
Traversable wormholes are
based on a type of
wormhole that might best be described as a modified Morris-Thorne-Kuhfittig
metric (after the Information Age theorists who first proposed the
basic
structure and theory).
The basic
properties of this class of wormhole are described below:
Spherical
and Stable:
Although they are generally referred to
as
“gateways” or “portals”
wormholes are in fact nothing like the picture of
simple two-dimensional doorways that such terms invoke.
Rather
they are complex spherical structures
that connect widely separated points in space-time.
While
non-spherical gateways are theoretically possible, the engineering and
practical difficulties of such structures are huge.
As
yet, no credible reports of non-spherical
wormholes have been made, although rumors that such structures have
been
produced by the archai or discovered in some remote region of space
continue to
persist.
Asymptotic
Flatness:
Wormholes connect two regions of space
that
are not normally adjacent to each other.
These two regions must be
‘asymptotically flat’ in order to keep the
wormhole stable.
In practice what this
means is that if a mass greater than that of the wormhole attempts to
enter the
wormhole mouth, the structure of the hole will become unstable and
implode into
a black hole.
Multi-Layered
Internal Structure:
All known types of wormhole possess a
similar internal structure, but this structure is most obvious in a
transport
gate.
Passage through a wormhole
from
mouth to throat is passage through a series of increasingly smaller
spheres;
the minimum radius sphere is at the throat.
The structure of a wormhole can be seen
in
the graphic below.
Modern wormholes are
consistently 327 Astronomical Units (A.U.s) in radius from the region
of
flat-space to the wormhole mouth.
|
Transition
|
Region of the wormhole
mouth extending
from flat space to a point some 3 Astronomical Units from the wormhole
throat.
|
|
Vortex
|
From 3 A.U.s to the
throat of the
wormhole is the region known as the Vortex. Space-time
closes in around the ship exponentially with decreasing distance and
velocities attained in the Transition can be fatal.
|
|
Caustic
|
The thin (>1cm) shell
of exotic
matter-energy surrounding the throat of the wormhole and holding it
open.
|
|
Throat
|
The region of maximum
space-time
constriction and linkage to the destination space-time.
The size of the Throat
dictates the
maximum size of any vessel transiting the wormhole.
If
a vessel is larger than the diameter of the Throat in any dimension
(length, height, width) it will come into contact with the walls of the
Throat and be destroyed.
Vessels larger than the
diameter of the
Throat that wish to transit the wormhole must either contract to a
smaller size or break up into independently maneuvering sections which
transit the gate individually and then reassemble on the other side.
|
Wormhole
Travel
Passage
through a wormhole
begins with
docking at the transport station orbiting one of the mouths of the
wormhole.
The mouth is the region where
the wormhole
metric becomes asymptotically flat. This
station is traditionally called Exit Station, as the travelers are
exiting this
region of space-time.
Exit stations are
located at the standard distance of 327 A.U.
From the
mouth of the wormhole,
the
transiting vessel travels inward through the Transition where the
wormhole
metric has been engineered to minimize the final mass of the wormhole
mouth.
Space-time curvature effects
and
tidal stresses are relatively mild, and most vessels have already
accelerated
to maximum velocity, executed turnaround, and are decelerating for
final
approach.
Particular care must be taken
at all times to minimize radial motion around the wormhole. Such
motion within the volume of the wormhole
results in the production of shear stresses on the vessel which, left
unchecked,
can result in its destruction.
At 3
A.U. from the wormhole
mouth the
ship
enters the Vortex.
Space-time closes in
around the ship exponentially with decreasing distance, and velocities
attained
in the Transition can be fatal due to the generation of massive tidal
forces.
The diverging lens effects
from the Throat
can be seen in the forward view, and the ship continues to decelerate
toward
rest.
Finally, the
ship crosses the Caustic
and
enters the Throat.
The Caustic is a thin
shell of exotic matter/energy that has been engineered to violate the
Averaged
Null Energy Condition (ANEC) to avoid the creation of an event horizon
leading
to the collapse of the wormhole into a black hole.
Passage
through the Caustic disrupts
computation and communication and the distortion of space can cause
light to
wind around the region again and again, creating an infinite set of
relativistic images.
Travelers will
notice two disruptions as the vessel passes through the Caustic to the
Throat
and back out again.
Passage
through the Throat of the
wormhole
is the most critical phase of the journey.
Tidal and shear stresses are
maximal, and contact with the boundaries of
the Throat leads to exposure to immense gravitational tides. Ships
making actual contact with the Throat
are shredded by gravitational strains, and even small energy releases
turn into
violent sprays of energetic radiation which can disrupt or destroy
computational
or hibernation substrates.
Since
neither computation nor
communication
can occur in the Caustic, transiting vessels shut down and follow
ballistic
paths during the transition.
The size,
g-tolerance, and acceleration of the vessel and its passengers
determine the
length of time required to traverse the Netherworld – the
traditional name of
this transition.
For a typical sophont
capable of sustaining moderate tidal stress, the transit time from Exit
Station
to the Throat to the Entrance Station at the destination takes
approximately
103 days.
In practice, most sophonts
undergo hibernation during transit; this reduces the transit time by
increasing
allowable acceleration, and adds an additional safety margin for
maneuvering.
Modern
Wormhole Ferries are capable of
crossing from Exit Station to Entrance Station in only 32 days. They
typically provide lavish virtual-reality
environments and the best vessels provide Known Net access during most
of the
journey. Of course, all communications and virtual realities shut down
during passage
through the Netherworld with system restart and acceleration back
towards
Entrance station commencing as soon as the wormhole transition is
complete.
Wormhole
Sizes:
The size of a wormhole is primarily
determined by the space-time engineering capability of the creating
transapient.
While other factors such as
energy and mass availability, anticipated traffic flow, and even the
desires of
the local modosophont population can all play a role in determining a
gateway’s
dimensions, it is the Singularity level of the portal’s
creator that is the
ultimate arbiter of wormhole size. While
First and Second Singularity minds are incapable of wormhole creation,
each
S-level beyond these is characterized by the ability to both synthesize
wormhole gateways and to manufacture them in a manner that makes ever
more
efficient use of the available mass-energy required to create a gate
and expand
it up to the desired size in minimal time. The table below provides
information
on representative wormhole properties versus the S-level creating them.
As of
this writing, the largest
wormholes
ever observed have been no more than 100 km in radius.
While
observations of the apparent abilities
of the archai in the field of wormhole engineering, as well as
information
gained from rare interviews, have led some researchers to speculate
that even
larger gates are possible, no such portals have ever been observed. This
has led other observers to speculate
that some upper limit of stability or practicality prevents the archai
from
creating such.
Others have hypothesized
the existence of vast, deep space portals thousands or tens of
thousands of
kilometers across, used exclusively by the archai for their own
mysterious
purposes.
Perhaps the only real
certainty
that can be gleaned from these various positions is that all are
equally
nebulous and lacking in any definite evidence of any description.
Traversable
Wormhole Masses (kg) and Expansion Rates
|
Radius
(meters)
|
Toposophic
Level
|
|
|
3
|
4
|
5
|
6
|
Ideal
Mass
|
|
1
|
1.3690E+25
|
1.3690E+22
|
1.3690E+19
|
1.3690E+16
|
1.369E+13
|
|
10
|
1.3690E+27
|
1.3690E+24
|
1.3690E+21
|
1.3690E+18
|
1.369E+15
|
|
100
|
1.3690E+29
|
1.3690E+26
|
1.3690E+23
|
1.3690E+20
|
1.369E+17
|
|
1000
|
1.3690E+31
|
1.3690E+28
|
1.3690E+25
|
1.3690E+22
|
1.369E+19
|
|
10000
|
1.3690E+33
|
1.3690E+30
|
1.3690E+27
|
1.3690E+24
|
1.369E+21
|
|
100000
|
1.3690E+35
|
1.3690E+32
|
1.3690E+29
|
1.3690E+26
|
1.369E+23
|
|
Comparison
Masses (kg)
|
|
Wormhole
Expansion Rates by Toposophic Level
|
|
1
km asteroid
|
1.0E+12
|
|
Level
|
Rate
of Expansion of Wormhole Radius
|
|
Luna
|
7.35E+22
|
|
3
|
1
meter per month
|
|
Earth
|
5.97E+24
|
|
4
|
1
meter per day
|
|
Jupiter
|
1.90E+27
|
|
5
|
2
meters per day
|
|
Sol
|
1.99E+30
|
|
6
|
4
meters per day
|
Communicable
Wormholes
A
simpler class of wormhole to
construct
is
a Communicable or Comm-gauge Wormhole.
In this case
tidal forces and proper transit time are not a consideration since only
null
geodesics (light beams) traverse the throat.
However, this is compensated
for by the difficulty entailed in
attempting stabilization of wormholes with small masses.
Because
destabilization can result from the
close passage of as little as 1% of the wormhole rest-mass, exotic
gravitational artifacts are enough to convert microscopic wormholes
into
microscopic black holes.
This has a
number of other space-time engineering uses, but for the purpose of
wormhole
construction, microscopic, so-call comm-gauge wormholes require
transapient
stabilization.
Comm-gauge
wormholes are generally of
the
class of wormhole known as Hayward
wormholes, which are attractive for communication purposes because
asymptotic
flatness requirements are reduced to only ten thousand times the
wormhole
radius.
This allows decreased
distances
between communication routers centered on the communicable wormhole
gateway.
Although they
have several traits which
make them useful communication tools, Hayward
class wormholes are not without their disadvantages.
Due
to the nature of their structure, Hayward
holes are vastly
more massive compared to their size than a modified MTK wormhole of
equivalent
dimensions.
A 100 meter Hayward
wormhole, if one were ever built,
would mass some 6.73E30 kilograms or nearly three and a half solar
masses.
In practice comm-gauge
wormhole links are
measured in dimensions ranging from nanometers to millimeters and have
correspondingly more manageable masses.
A link of 1-nanometer radius
would only mass some 6.73E19 kilograms or
approximately 7% of the mass of the Sol System asteroid Ceres (prior to
its
reengineering during the Interplanetary Age).
Wormhole
Bandwidth
Comm-gauge wormholes play a vital yet
curious role in the life of Terragens Civilization and the transapient
intelligences which rule it.
In one
instance these devices are the source of one of modern
civilization’s greatest
strengths: the ability to transmit information across vast distances in
almost
zero time.
In the other, they are a
great limitation, channeling and restricting the thoughts and
communications of
all levels of civilization to a fraction of their full potential. The
issue is one of bandwidth.
Modern civilization employs massive data
flows to operate and maintain itself, ranging from the statistical
modeling
simulations of traffic control and planetary weather systems to the
uploaded
minds of trillions of sophonts to the vast and mysterious thoughts of
the AI
Gods themselves.
To be most effective
across the distances encompassed by Terragens culture, these data
streams must
be routed to their destinations as quickly as possible, which should
mean being
sent via wormhole.
Yet wormholes have a
limitation.
Due to the nature of their
structure, they are severely limited in the amount of information that
can pass
through them at any given moment. By
the
standards of past cultures this quantity of data might have seemed so
great as
to be able to meet any conceivable demand.
But by the standards of our
modern age, even the most capable wormhole
link is woefully inadequate to match the data output of a modest star
system.
This situation
lends itself to no easy
solution, although various methods are employed to at least alleviate
the
problem.
Data compression techniques
have been raised to a high art to compact a maximum amount of
information into
the smallest possible data burst. High
energy data lasers in the petawatt range are a standard part of
wormhole data networks
in nearly all of the most developed systems while gigawatt links are
the norm
practically everywhere else.
On occasion
great “data freighters” will be employed to record
and transit especially
important data across the Nexus. And
for
the lowest priority or (conversely) largest data packages conventional
communications lasers operating across “normal
space’ volumes are used. This
is because the communications shared by
the archai may become so large and complex that it literally takes a
fraction
of the time to send them “conventionally” across
interstellar space as it would
take to transmit them using the limited bandwidth of a wormhole.
Despite
these limitations, the
importance
of wormhole links and the near instant communication they provide among
millions
of worlds cannot be underestimated.
Without the wormholes,
civilization as we know it could not exist.
Hayward
(Comm-gauge) Wormholes:
Sizes, Masses, and Bandwidths
|
Transmission
Rate (bits per second – bps)
|
|
Radius
|
Mass
|
Power
(watts – W)
|
|
(meters)
|
(kg)
|
1W
|
1.00E+03W
|
1.00E+06W
|
1.00E+09W
|
1.00E+12W
|
1.00E+15W
|
|
1.00E-12
|
6.734E+16
|
4.0479E+15
|
7.1983E+17
|
1.2801E+20
|
2.2763E+22
|
4.0479E+24
|
7.1983E+26
|
|
1.00E-09
|
6.734E+19
|
1.2801E+17
|
2.2763E+19
|
4.0479E+21
|
7.1983E+23
|
1.2801E+26
|
2.2763E+28
|
|
1.00E-06
|
6.734E+22
|
4.0479E+18
|
7.1983E+20
|
1.2801E+23
|
2.2763E+25
|
4.0479E+27
|
7.1983E+29
|
|
1.00E-03
|
6.734E+25
|
1.2801E+20
|
2.2763E+22
|
4.0479E+24
|
7.1983E+26
|
1.2801E+29
|
2.2763E+31
|
|
Note:
All values below this line are theoretical.
|
|
1.00E+00
|
6.734E+28
|
4.0479E+21
|
7.1983E+23
|
1.2801E+26
|
2.2763E+28
|
4.0479E+30
|
7.1983E+32
|
|
1.00E+03
|
6.734E+31
|
1.2801E+23
|
2.2763E+25
|
4.0479E+27
|
7.1983E+29
|
1.2801E+32
|
2.2763E+34
|
|
1.00E+06
|
6.734E+34
|
4.0479E+24
|
7.1983E+26
|
1.2801E+29
|
2.2763E+31
|
4.0479E+33
|
7.1983E+35
|
Failure
Modes
Under
certain circumstances wormholes
can
become unstable.
While the wormhole
solution is reasonably stable, under some conditions it is subject to
instabilities that can cause either explosion to an inflationary
universe, or
collapse to a black hole.
For collapse, some
70% of the wormhole mass-energy is radiated away; the rest becomes the
mass of
the black hole.
For explosion, radiated
energy self-reinforces leading to inflation into a new space-time.
Instabilities can arise in
three forms:
1)
In
practice,
transapient stabilization technologies are able to compensate for such
small
instabilities with relative ease.
However, as the energy or
mass involved increases, the ability of
stabilizer systems to compensate becomes ever smaller until a point of
uncontrollable instability is reached when the perturbing mass-energy
exceeds
the rest mass of the wormhole and asymptotic flatness constraints are
violated.
2) Linear
instabilities: Wormholes
are typically subjected to linear
instabilities during the deployment phase, right after the wormhole has
been
inflated from the quantum regime, but before it is inflated to
traversable
size.
These instabilities come from
Lorentz contraction during the transport of the wormhole mouths to
their final
destinations and are typically limited to perturbations of less than
50% of the
wormhole rest mass.
For this reason,
wormhole transport velocities are constrained to less than .74c.
It
should be
noted that this constraint on wormhole transport velocities does not
apply when
the wormhole mouths are being transported within a Void bubble. Within
such bubbles space-time is
asymptotically flat and time-dilation and Lorentz contraction effects
do not
occur.
Wormhole mouths transported
by
Void drive can travel at any velocity below c without harmful effects.
3) Chronodynamic
instability: Under
certain circumstances a wormhole can
become a time machine, resulting in its immediate destruction. Because
the formation of a Closed Timelike Curve
immediately generates a Cauchy horizon, a wormhole will be destabilized
any
time a CTC exists.
The procedure for
creating a CTC is:
· Create a wormhole
· Induce a time
shift between the
mouths
· Bring the mouths
close enough
together so that the distance through the simply-connected region
(“normal
space”) is less than the time shift.
The
simplest way to induce a
time shift
is
to move one mouth at relativistic velocity.
This is the usual course of
events in deployment of a wormhole gate
between systems.
However, once brought
to the target system, the wormhole is inflated and remains in far orbit
around
the star, so a normal wormhole will not create a time machine.
General
relativistic means for
inducing
time shift exist (e.g. orbit around massive objects), but they are of
no
engineering concern.
Of far
greater concern is the
possibility
of a “Roman” configuration (named for an
Information Age physicist who first
considered the idea) involving multiple wormholes.
Such
a configuration results when a set of
wormholes by themselves are not time machines, but form a network that does
produce a time machine.
For the
simplest two-wormhole
configuration, there are essentially 3 requirements:
To avoid
Roman time machines,
one of two
criteria are sufficient:
As a
concrete example, a
linelayer with
1g
of acceleration will achieve .7c in 10 months.
Neglecting acceleration and
turnaround (which is a small fraction of the
total trip), the travel time as measured by the home system will be ~14
years;
the linelayer will measure ~10 years.
Upon arrival, if a second
linelayer is sent back to the original system,
it will generate a CTC when ~5 ly distant.
The Chronodynamics
significantly restricts wormhole placement and the
overall structure of the Wormhole Nexus and Known Net.
In sum,
wormholes must be
stabilized by
transapient systems.
Larger wormholes
are more stable, but the results of disaster are correspondingly
greater.
Chronology Protection
mandates careful
arrangement of wormhole networks.
This wormhole has a polyhedral
Infrastructure shell surrounding the Caustic;
the controlling Gate Archai dwells
inside this structure
