Since it is
not obvious that one can rid oneself of all constraints in realistic
models, let us examine the argument that time travel is implausible, and
we should think it unlikely to exist in our world, in so far as it
implies such constraints. The argument goes something like the
following. In order to satisfy such constraints one needs some
pre-established divine harmony between the global (time travel)
structure of space-time and the distribution of particles and fields on
space-like surfaces in it. But it is not plausible that the actual
world, or any world even remotely like ours, is constructed with divine
harmony as part of the plan. In fact, one might argue, we have empirical
evidence that conditions in any spatial region can vary quite
arbitrarily. So we have evidence that such constraints, whatever they
are, do not in fact exist in our world. So we have evidence that there
are no closed time-like lines in our world or one remotely like it. We
will now examine this argument in more detail by presenting four
possible responses, with counterresponses, to this argument.
Response
1. There is nothing implausible or new about such constraints. For
instance, if the universe is spatially closed, there has to be enough
matter to produce the needed curvature, and this puts constraints on the
matter distribution on a space-like hypersurface. Thus global
space-time structure can quite unproblematically constrain matter
distributions on space-like hypersurfaces in it. Moreover we have no
realistic idea what these constraints look like, so we hardly can be
said to have evidence that they do not obtain.
Counterresponse 1. Of
course there are constraining relations between the global structure of
space-time and the matter in it. The Einstein equations relate curvature
of the manifold to the matter distribution in it. But what is so
strange and implausible about the constraints imposed by the existence
of closed time-like curves is that these constraints in essence have
nothing to do with the Einstein equations. When investigating such
constraints one typically treats the particles and/or field in question
as test particles and/or fields in a given space-time, i.e. they are
assumed not to affect the metric of space-time in any way. In typical
space-times without closed time-like curves this means that one has, in
essence, complete freedom of matter distribution on a space-like
hypersurface. (See response 2 for some more discussion of this issue).
The constraints imposed by the possibility of time travel have a quite
different origin and are implausible. In the ordinary case there is a
causal interaction between matter and space-time that results in
relations between global structure of space-time and the matter
distribution in it. In the time travel case there is no such causal
story to be told: there simply has to be some pre-established harmony
between the global space-time structure and the matter distribution on
some space-like surfaces. This is implausible.
Response 2.
Constraints upon matter distributions are nothing new. For instance,
Maxwell's equations constrain electric fields E on an initial surface to
be related to the (simultaneous) charge density distribution by the
equation = div(E). (If we assume that the E field is generated solely by
the charge distribution, this conditions amounts to requiring that the E
field at any point in space simply be the one generated by the charge
distribution according to Coulomb's inverse square law of
electrostatics.) This is not implausible divine harmony. Such
constraints can hold as a matter of physical law. Moreover, if we had
inferred from the apparent free variation of conditions on spatial
regions that there could be no such constraints we would have mistakenly
inferred that = div(E) could not be a law of nature.
Counterresponse
2. The constraints imposed by the existence of closed time-like lines
are of quite a different character from the constraint imposed by =
div(E). The constraints imposed by = div(E) on the state on a space-like
hypersurface are: (i) local constraints (i.e. to check whether the
constraint holds in a region you just need to see whether it holds at
each point in the region), (ii) quite independent of the global
space-time structure, (iii) quite independent of how the space-like
surface in question is embedded in a given space-time, and (iv) very
simply and generally stateable. On the other hand, the consistency
constraints imposed by the existence of closed time-like curves (i) are
not local, (ii) are dependent on the global structure of space-time,
(iii) depend on the location of the space-like surface in question in a
given space-time, and (iv) appear not to be simply stateable other than
as the demand that the state on that space-like surface embedded in such
and such a way in a given space-time, do not lead to inconsistency. On
some views of laws (e.g. David Lewis' view) this plausibly implies that
such constraints, even if they hold, could not possibly be laws. But
even if one does not accept such a view of laws, one could claim that
the bizarre features of such constraints imply that it is implausible
that such constraints hold in our world or in any world remotely like
ours.
Response 3. It would be strange if there are constraints in the
non-time travel region. It is not strange if there are constraints in
the time travel region. They should be explained in terms of the
strange, self-interactive, character of time travel regions. In this
region there are time-like trajectories from points to themselves. Thus
the state at such a point, in such a region, will, in a sense, interact
with itself. It is a well-known fact that systems that interact with
themselves will develop into an equilibrium state, if there is such an
equilibrium state, or else will develop towards some singularity.
Normally, of course, self-interaction isn't true instantaneous
self-interaction, but consists of a feed-back mechanism that takes time.
But in time travel regions something like true instantaneous
self-interaction occurs. This explains why constraints on states occur
in such time travel regions: the states ‘ab initio’ have to be
‘equilibrium states’. Indeed in a way this also provides some picture of
why indeterminism occurs in time travel regions: at the onset of
self-interaction states can fork into different equi-possible
equilibrium states.
Counterresponse 3. This is explanation by woolly
analogy. It all goes to show that time travel leads to such bizarre
consequences that it is unlikely that it occurs in a world remotely like
ours.
Response 4. All of the previous discussion completely misses
the point. So far we have been taking the space-time structure as given,
and asked the question whether a given time travel space-time structure
imposes constraints on states on (parts of) space-like surfaces.
However, space-time and matter interact. Suppose that one is in a
space-time with closed time-like lines, such that certain counterfactual
distributions of matter on some neighborhood of a point p are ruled out
if one holds that space-time structure fixed. One might then ask "Why
does the actual state near p in fact satisfy these constraints? By what
divine luck or plan is this local state compatible with the global
space-time structure? What if conditions near p had been slightly
different?". And one might take it that the lack of normal answers to
these questions indicates that it is very implausible that our world, or
any remotely like it, is such a time travel universe. However the
proper response to these question is the following. There are no
constraints in any significant sense. If they hold they hold as a matter
of accidental fact, not of law. There is no more explanation of them
possible than there is of any contingent fact. Had conditions in a
neighborhood of p been otherwise, the global structure of space-time
would have been different. So what? The only question relevant to the
issue of constraints is whether an arbitrary state on an arbitrary
spatial surface S can always be embedded into a space-time such that
that state on S consistently extends to a solution on the entire
space-time.
But we know the answer to that question. A well-known
theorem in general relativity says the following: any initial data set
on a three dimensional manifold S with positive definite metric has a
unique embedding into a maximal space-time in which S is a Cauchy
surface (see e.g. Geroch and Horowitz 1979, p. 284 for more detail),
i.e. there is a unique largest space-time which has S as a Cauchy
surface and contains a consistent evolution of the initial value data on
S. Now since S is a Cauchy surface this space-time does not have closed
time like curves. But it may have extensions (in which S is not a
Cauchy surface) which include closed timelike curves, indeed it may be
that any maximal extension of it would include closed timelike curves.
(This appears to be the case for extensions of states on certain
surfaces of Taub-NUT space-times. See Earman and Smeenk 1999). But these
extensions, of course, will be consistent. So properly speaking, there
are no constraints on states on space-like surfaces. Nonetheless the
space-time in which these are embedded may or may not include closed
time-like curves.
Counterresponse 4. This, in essence, is the
stonewalling answer which we indicated at the beginning of section 2.
However, whether or not you call the constraints imposed by a given
space-time on distributions of matter on certain space-like surfaces
‘genuine constraints’, whether or not they can be considered lawlike,
and whether or not they need to be explained, the existence of such
constraints can still be used to argue that time travel worlds are so
bizarre that it is implausible that our world or any world remotely like
ours is a time travel world.
Suppose that one is in a time travel
world. Suppose that given the global space-time structure of this world,
there are constraints imposed upon, say, the state of motion of a ball
on some space-like surface when it is treated as a test particle, i.e.
when it is assumed that the ball does not affect the metric properties
of the space-time it is in. (There is lots of other matter that, via the
Einstein equation, corresponds exactly to the curvature that there is
everywhere in this time travel worlds.) Now a real ball of course does
have some effect on the metric of the space-time it is in. But let us
consider a ball that is so small that its effect on the metric is
negligible. Presumably it will still be the case that certain states of
this ball on that space-like surface are not compatible with the global
time travel structure of this universe.
This means that the actual
distribution of matter on such a space-like surface can be extended into
a space-time with closed time-like lines, but that certain
counterfactual distributions of matter on this space-like surface can
not be extended into the same space-time. But note that the changes made
in the matter distribution (when going from the actual to the
counterfactual distribution) do not in any non-negligible way affect the
metric properties of the space-time. Thus the reason why the global
time travel properties of the counterfactual space-time have to be
significantly different from the actual space-time is not that there are
problems with metric singularities or alterations in the metric that
force significant global changes when we go to the counterfactual matter
distribution. The reason that the counterfactual space-time has to be
different is that in the counterfactual world the ball's initial state
of motion starting on the space-like surface, could not ‘meet up’ in a
consistent way with its earlier self (could not be consistently
extended) if we were to let the global structure of the counterfactual
space-time be the same as that of the actual space-time. Now, it is not
bizarre or implausible that there is a counterfactual dependence of
manifold structure, even of its topology, on matter distributions on
spacelike surfaces. For instance, certain matter distributions may lead
to singularities, others may not. We may indeed in some sense have
causal power over the topology of the space-time we live in. But this
power normally comes via the Einstein equations. But it is bizarre to
think that there could be a counterfactual dependence of global
space-time structure on the arrangement of certain tiny bits of matter
on some space-like surface, where changes in that arrangement by
assumption do not affect the metric anywhere in space-time in any
significant way. It is implausible that we live in such a world, or that
a world even remotely like ours is like that.
Let us illustrate this
argument in a different way by assuming that wormhole time travel
imposes constraints upon the states of people prior to such time travel,
where the people have so little mass/energy that they have negligible
effect, via the Einstein equation, on the local metric properties of
space-time. Do you think it more plausible that we live in a world where
wormhole time travel occurs but it only occurs when people's states are
such that these local states happen to combine with time travel in such
a way that nobody ever succeeds in killing their younger self, or do
you think it more plausible that we are not in a wormhole time travel
world?[4]
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