Space-Time-Matter: Finite Projective Geometry as a Quantum World with Elementary Particles
Sommerfeld Theory Colloquium (ASC)
English - June 26, 2024 15:30 - 1 hour - 1.9 GB Video - ★★★★★ - 2 ratingsScience physics theoretical physics colloquium distinguished speakers astrophysics particle physics solid state physics quantum physics gravity Homepage Download Apple Podcasts Google Podcasts Overcast Castro Pocket Casts RSS feed
A unified theory for space-time and matter might be based on finite
projective geometries instead of differentiable manifolds and gauge
groups. Each point is equipped with a quadratic form over a finite Galois field which define neighbors in the finite set of points.
Due to the projective equivalence of all quadratic forms this world
is necessarily a 4-dimensional Lorentz-invariant space-time with a
gauge symmetry G(3)xG(2)xG(1) for internal points which represent elementary particle degrees of freedom. Matter appears as a
geometric distortion by an inhomogeneous field of quadrics and all
physical properties (spins, charges) of the standard model seem to
follow from its geometric structure in a continuum limit. The finiteness inevitably induces a fermionic quantization of all matter fields
and a bosonic for gauge fields. This unity of space-time and matter
was already sought 1918 by Hermann Weyl in a gauge theory as an
extension of Einstein’s general theory of relativity, but not found -
probably because of the assumption of a continuous geometry.