二维引力模型中的沃德特性:利用完全正则化无关的数学策略重新审视反常振幅

IF 3.4 3区 物理与天体物理 Q2 PHYSICS, NUCLEAR
G Dallabona, P G de Oliveira, O A Battistel
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引用次数: 0

摘要

我们详细研究了一个具有韦尔费米子的简单二维模型中的反常引力振幅。我们采用了一种数学策略,完全避免了处理发散微扰振幅的正则化处方。与使用正则化方法的研究不同,这种策略完全依赖于积分运算线性的有效性,避免了在中间计算过程中修改振幅。此外,我们还采用了任意的内环矩路由,代表了最一般的分析方案。不出所料,我们的结果表明,表面项在保持振幅的对称性和确保结果的数学一致性方面起着至关重要的作用。值得注意的是,我们的最终扰动振幅可以转换成使用任何特定正则化处方得到的形式。我们考虑了三种常见情况,其中一种恢复了引力异常的传统结果。然而,我们证明这种情况不可避免地破坏了积分的线性,导致了不理想的数学状况。由于我们的策略具有普遍性,因此得出的结论简洁而透明,这在使用正则化技术的类似研究中是不明显的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ward identities in a two-dimensional gravitational model: anomalous amplitude revisited using a completely regularization-independent mathematical strategy
We present a detailed investigation of the anomalous gravitational amplitude in a simple two-dimensional model with Weyl fermions. We employ a mathematical strategy that completely avoids any regularization prescription for handling divergent perturbative amplitudes. This strategy relies solely on the validity of the linearity of the integration operation and avoids modifying the amplitudes during intermediate calculations, unlike studies using regularization methods. Additionally, we adopt arbitrary routings for internal loop momenta, representing the most general analysis scenario. As expected, we show that surface terms play a crucial role in both preserving the symmetry properties of the amplitude and ensuring the mathematical consistency of the results. Notably, our final perturbative amplitude can be converted into the form obtained using any specific regularization prescription. We consider three common scenarios, one of which recovers the traditional results for gravitational anomalies. However, we demonstrate that this scenario inevitably breaks the linearity of integration, leading to an undesirable mathematical situation. This clean and transparent conclusion, enabled by the general nature of our strategy, would not be apparent in similar studies using regularization techniques.
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来源期刊
CiteScore
7.60
自引率
5.70%
发文量
105
审稿时长
1 months
期刊介绍: Journal of Physics G: Nuclear and Particle Physics (JPhysG) publishes articles on theoretical and experimental topics in all areas of nuclear and particle physics, including nuclear and particle astrophysics. The journal welcomes submissions from any interface area between these fields. All aspects of fundamental nuclear physics research, including: nuclear forces and few-body systems; nuclear structure and nuclear reactions; rare decays and fundamental symmetries; hadronic physics, lattice QCD; heavy-ion physics; hot and dense matter, QCD phase diagram. All aspects of elementary particle physics research, including: high-energy particle physics; neutrino physics; phenomenology and theory; beyond standard model physics; electroweak interactions; fundamental symmetries. All aspects of nuclear and particle astrophysics including: nuclear physics of stars and stellar explosions; nucleosynthesis; nuclear equation of state; astrophysical neutrino physics; cosmic rays; dark matter. JPhysG publishes a variety of article types for the community. As well as high-quality research papers, this includes our prestigious topical review series, focus issues, and the rapid publication of letters.
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