# Random fields, large deviations and triviality in quantum field theory.   Part I

**Authors:** Adnan Aboulalaa

arXiv: 1903.09621 · 2023-01-24

## TL;DR

This paper investigates the existence and triviality of four-dimensional Euclidean quantum scalar fields using large deviations, showing that the fields become trivial and non-stable as the ultraviolet cutoff is removed.

## Contribution

It applies large deviations techniques to demonstrate the non-existence and triviality of quantum scalar fields in four dimensions, extending results to vector fields and polynomial Lagrangians.

## Key findings

- The density of regularized measures tends to zero almost surely as cutoff is removed.
- Normalization sequences diverge, indicating non-ultraviolet stability.
- Results hold for vector fields and polynomial Lagrangians.

## Abstract

The issue of the existence and possible triviality of the Euclidean quantum scalar field in dimension 4 is investigated by using some large deviations techniques. As usual, the field $\varphi_{d}^{4}$ is obtained as a limit of regularized fields $\varphi_{k}^{4}$ associated with a probability measures $\mu_{k,V}$, where $k, V$ represent ultraviolet and volume cutoffs. The result obtained is that in a fixed volume, the almost sure limit (as $k \rightarrow \infty$) of the density of $\mu_{k,V}$, with respect to the Gaussian free field measure, exists and is equal to $0$, when the coupling constant is not vanishing. This implies that $\mu_{k,V}$ can not have a strong limit as the ultraviolet cutoff is removed. Furthermore, the normalization sequence $Z_{k,V}=E e^{-{\cal A}_{k,V}}$ is divergent as $k \rightarrow \infty$ for dimensions $d\geq4$ when the vacuum renormalization is lower than some threshold, which leads to the non ultraviolet stability of the field in this case. These assertions are also valid for vector fields and can be extended to polynomial Lagrangians.

## Full text

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## References

61 references — full list in the complete paper: https://tomesphere.com/paper/1903.09621/full.md

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Source: https://tomesphere.com/paper/1903.09621