Thanks to Sabine for inviting me to do a guest post. In her book, “
Lost in Math,” I mentioned the criteria of “geometric naturalness” for
judging theories of fundamental physics. Here I would like to give a
personal definition of this and expand on it a bit.
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| Figure: Lowest million roots of E8+++ projected from eleven dimensions.
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As physicists we unabashedly steal tools from mathematicians. And we
don’t usually care where these tools come from or how they fit into
the rest of mathematics, as long as they’re useful. But as we learn
more mathematics, aesthetics from math influences our minds. The first
place I strongly encountered this was in General Relativity. The tools
of
metric,
covariant derivative,
connection, and
curvature of a
manifold
were irresistibly attractive structures that lured my impressionable
soul into the mathematical world of differential geometry.
Studying differential geometry, I learned that the
tensors I
had been manipulating for physics calculations represent
coordinate-invariant objects describing local maps between vector
fields. That multi-dimensional integrals are really integrals over
differential forms, with changing order of integration
corresponding to 1-forms anti-commuting. That a spacetime metric is a
local map from two vector fields to a scalar field, which can also be
described using a
frame – a vector-valued 1-form field
mapping spacetime vectors into another vector space. And that the
connection and curvature fields related to this frame completely
describe the local geometry of a manifold.
With exposure to differential geometry and GR, and impressed by GR’s
amazing success, I came to believe that our universe is fundamentally
geometric. That ALL structures worth considering in fundamental
theoretical physics are
geometrically
natural, involving
maps between vector fields on a manifold, and coordinate-invariant
operations on those maps. This belief
was further strengthened by understanding Lie groups and gauge theory
from a geometrically natural point of view.
Students usually first encounter Lie groups in an algebraic context,
with a commutator bracket of two physical rotation generators giving a
third. Then we learn that these algebraic generators correspond to
tangent vector fields on a 3D Lie group manifold called SO(3). And the
commutator bracket of two generators corresponds to the Lie derivative
of one generator vector field with respect to the other – a
natural
geometric operation.
The principle of geometric naturalness in fundamental physics has its
greatest success in gauge theory. A gauge theory with N-dimensional
gauge Lie group, G, can be understood as an (N+4)-dimensional
total space manifold, E, over 4-dimensional spacetime, M.
Spacetime here is not independent, but incorporated in the total
space. A gauge potential field in spacetime corresponds to a 1-form
Ehresmann connection field over the total space, mapping
tangent vectors into the
Vertical tangent vector space of Lie
group
fibers, or equivalently into the vector space of the
Lie algebra. The curvature of this connection corresponds to the
geometry of the total space, and is physically the gauge field
strength in spacetime. For physics, the action is the total space
integral of the curvature and its Hodge dual.
The strong presence of geometric naturalness in
fundamental
physics is incontrovertible. But is it ALL geometrically natural?
Things get more complicated with fermions. We can enlarge the total
space of a gauge theory to include an
associated bundle with
fibers transforming appropriately as a fermion
representation
space under the gauge group. This appearance of a representation
space is ad-hoc; although, with the Peter-Weyl theorem identifying
representations with the excitation spectrum of the Lie group
manifold, it is arguably geometric and not just algebraic. (The rich
mathematics of representation theory has been greatly
under-appreciated by physicists.) But the physically essential
requirement that fermion fields be anti-commuting
Grassmann
numbers is not geometrically natural at all. Here the religion of
geometric naturalness appears to have failed... So physicists strayed.
Proponents of
supersymmetry wholeheartedly embraced
anti-commuting numbers, working on theories in which every field, and
thus every physical elementary particle, has a Grassmann-conjugate
partner – with physical particles having superpartners. But despite
eager anticipation of their arrival, these superpartners are nowhere
to be seen. The SUSY program has failed. Having embraced
supersymmetry, string theorists are also in a bad place. And even
without SUSY, string theory is geometric – involving embedding
manifolds in other manifolds – but is not geometrically natural as
defined above. And the string theory program has spectacularly failed
to deliver on its promises.
What about the rebels? The Connes-Lott-Chamseddine program of
non-commutative geometry takes the spectral representation
space of fermions as fundamental, and so abandons geometric
naturalness. Eric Weinstein's
Geometric Unity program
promotes the metric to an Ehresmann connection on a 14-dimensional
total space, fully consistent with geometric naturalness, but again
there are ad-hoc representation spaces and non-geometric Grassmann
fields. The
Loop Quantum Gravity program, ostensibly the
direct descendent of GR, proceeds with the development of a
fundamentally quantum description that is discrete – and thus not
geometrically natural. Other rebels, including Klee Irwin's group,
Wolfram, Wen, and many others, adopt fundamentally discrete structures
from the start and ignore geometric naturalness entirely. So I guess
that leaves me.
Enchanted with geometric naturalness, I spent a very long time trying
to figure out a more natural description of fermions. In 2007 I was
surprised and delighted to
find that the representation space of one generation of Standard Model
fermions, acted on by gravity and gauge fields, exists as part of the
largest simple exceptional Lie group, E8. My critics were
delighted that E8 also
necessarily contains a generation of mirror fermions, which, like
superparticles, are not observed.
My attempts to address this issue
were unsatisfactory, but I made other progress. In 2015 I developed a
model,
Lie Group
Cosmology, that showed how spacetime could emerge within a Lie
group, with physical fermions appearing as geometrically natural,
anti-coummuting orthogonal 1-forms, equivalent to Grassmann numbers in
calculations. For the first time, there was a complete and
geometrically natural description of fermions. But there was still the
issue of mirror fermions, which Distler and Garibaldi had used in 2009
to successfully kill the theory, claiming that there was “no known
mechanism by which it [any non-chiral theory] could reduce to a chiral
theory.” But they were wrong.
Unbeknownst to me, Wilczek and Zee had
solved
this problem in 1979. (Oddly, first published in a
conference proceedings
edited by my graduate advisor.) I wish they'd told me! Anyway, mirror
fermions can be confined (similarly to su(3) color confinement) by a
so(5) inside a so(8) which, by triality, leaves exactly three
generations of chiral fermions unconfined. Extending E8 to
infinite-dimensional Lie groups, such as very-extended E8+++ (see
Figure), this produces three generations and no mirrors. And, as I
wrote in 2007, one needs to consider infinite-dimensional Lie groups
anyway for a quantum description... something almost nobody talks
about.
No current unified theory includes quantum mechanics fundamentally as
part of its structure. But a truly unified theory must. And I believe
the ultimate theory will be geometrically natural. Canonical quantum
commutation relations are a Lie bracket, which can be part of a Lie
group in a geometrically natural description. I fully expect this will
lead to a beautiful quantum-unified theory – what I am currently
working on.
I never expected to find beauty in theoretical physics. I stumbled
into it, and into E8 in particular, when looking for a naturally
geometric description of fermions. But beauty is inarguably there, and
I do think it is a good guide for theory building. I also think it is
good for researchers to have a variety of aesthetic tastes for what
guides and motivates them. The high energy physics community has spent
far too much time following the bandwagon of superstring theory, long
after the music has stopped playing. It’s time for theorists to spread
out into the vast realm of theoretical possibilities and explore
different ideas.
Personally, I think the “naturalness” aesthetic of
fundamental constants being near 1 is a red herring – the universe
doesn’t seem to care about that. For my own guiding aesthetic of
beauty, I have adopted geometric naturalness and a balance of
complexity and simplicity, which I believe has served me well. If one
is going to be lost, mathematics is a wonderful place to wander
around. But not all those who wander are lost.
