Analysis of the Models for String Theory and Advanced Experiment Verification

Qiyi Zheng

doi:10.54097/y55nr281

Authors

Qiyi Zheng

DOI:

https://doi.org/10.54097/y55nr281

Keywords:

String theory, string cosmology, compactification, quantum gravity.

Abstract

As a matter of fact, string theory remains a widely analyzed and investigated target in theoretical physics in recent years. In retrospect, the high expectations of string theory when it first appeared contrast with its unachievable requirement of experimental validation at a first glance. Throughout decades of evolution, string theory has developed some more mature applications in string cosmology and string phenomenology rather than just looking for a direct verification of its existence. With this in mind, this study focuses on the specific theories the bosonic string theory has evolved to, and how they are applied in modern theoretical physics, including the string inflation models, KKLT scenario and F-theory. In addition, plausible experiments and its connection with gravitational waves is also discussed, along with the impact of machine learning on evidence seeking of strings. According to the analysis, the state-of-art results are demonstrated and the current limitations as well as prospects are discussed.

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