What question did this study set out to answer?

The aim is to analyze the ultraviolet behavior of a four-dimensional sigma model with target manifold Sp(2N,R)/U(N) equipped with a specific metric.

April 26, 2026Open Access

Lattice Verification and Higher-Order Seeley-DeWitt Analysis of the 4D Sigma Model on Sp(2N,R)/U(N)

Key Points

The aim is to analyze the ultraviolet behavior of a four-dimensional sigma model with target manifold Sp(2N,R)/U(N) equipped with a specific metric.
Completing the higher-order heat-kernel analysis for closed-form computations of Seeley DeWitt coefficients.
Implementing fourth-order functional-renormalization-group truncation method for stability checks.
Conducting simulations via Lattice Monte Carlo and applying Wilson flow in a specific geometric setting.
Higher-order analysis confirmed the Seeley DeWitt coefficient for N=28 as a6 = −1.259×10⁹ to high accuracy.
FRG-IV updates showed a negative beta function leading to stability throughout coupling ranges.
Lattice flow analysis confirmed a negative beta function across several parameters, supporting non-perturbative predictions.

Abstract

We complete the ultraviolet analysis of the four-dimensional nonlinear sigma model with target manifold M = Sp(2N,R)/U(N) equipped with the Fisher-Bures metric, the fundamental sigma model of the Vacuum Time Geometry theory. Building on the perturbative and functional-renormalization-group (FRG) results of the companion paper Paper 2, we present three new, mutually independent confirrmations of asymptotic freedom at all couplings T > 0: (i) Higher-order heat-kernel analysis. We compute the Seeley DeWitt coefcient a6 in closed form for Sp(2N,R)/U(N), using the covariantly-constant Riemann tensor of the symmetric space. For N = 28 we obtain a6 = −2040309414769/1620 ≃ −1.259×109, verifed against direct Lie-algebra computation for N = 2, . . . , 7 to relative accuracy ≤ 6.11×10−16. The closed-form expressions for the cubic Riemann invariants I1 = RijknRijlpRknlp and I2 = RijknRilkpRjlnp are new. (ii) Fourth FRG truncation (FRG-IV). Upgrading the heat-kernel truncation of Paper 2 (FRG-III, through a2) to include a4 and a6 yields a correction of ∼ 0.2% relative to FRG-III across T ∈ 0.5, 15. The beta function remains strictly negative, confirming the stability of the non-perturbative prediction. (iii) Lattice Monte Carlo and Wilson flow. We simulate the sigma model directly on Sp(4,R)/U(2) (Siegel upper half-space H2) on a 44 hypercubic lattice with Metropolis dynamics in the tangent space and implement a Lüscher-type RK3 gradient flow adapted to the target geometry. The flow-defined beta function is negative for every coupling T ∈ 0.5, 5 and every ow time, in qualitative agreement with FRG-III/IV. At T = 5.0, perturbation theory predicts βpert = +1.81 while the lattice yields βflow ≃ −1.19, confirrming that the perturbative zero T ∗ ≃ 6.3 is an artefact of two-loop truncation. Together with Paper 2, these results close Axis 2 of the Vacuum Time Geometry programme: the sigma model has no ultraviolet fixed point at finite coupling, flows toward the Gaussian fixed point T = 0 from every initial condition probed, and is therefore asymptotically free in the non-perturbative sense-consistent across perturbation theory, four FRG truncation schemes, and direct lattice simulation.

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