Supersymmetric Theory and Models

Anticipating the Next Discoveries in Particle Physics Pub Date : 2017-12-16 DOI:10.1142/9789813233348_0006

H. Haber, Laurel Stephenson Haskins

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引用次数: 12

Abstract

In these introductory lectures, we review the theoretical tools used in constructing supersymmetric field theories and their application to physical models. We first introduce the technology of two-component spinors, which is convenient for describing spin-$1/2$ fermions. After motivating why a theory of nature may be supersymmetric at the TeV energy scale, we show how supersymmetry (SUSY) arises as an extension of the Poincar\'e algebra of spacetime symmetries. We then obtain the representations of the SUSY algebra and discuss its simplest realization in the Wess-Zumino model. In order to have a systematic approach for obtaining supersymmetric Lagrangians, we introduce the formalism of superspace and superfields and recover the Wess-Zumino Lagrangian. These methods are then extended to encompass supersymmetric abelian and non-abelian gauge theories coupled to supermatter. Since supersymmetry is not an exact symmetry of nature, it must ultimately be broken. We discuss several mechanisms of SUSY-breaking (both spontaneous and explicit) and briefly survey various proposals for realizing SUSY-breaking in nature. Finally, we construct the the Minimal Supersymmetric extension of the Standard Model (MSSM), and consider the implications for the future of SUSY in particle physics.

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超对称理论与模型

在这些导论讲座中，我们回顾了用于构造超对称场论的理论工具及其在物理模型中的应用。我们首先介绍了双分量旋量技术，它便于描述自旋-$1/2$费米子。在解释了为什么一个自然理论在TeV能量尺度上可能是超对称的之后，我们展示了超对称(SUSY)是如何作为时空对称的庞加莱代数的延伸而产生的。然后，我们得到了SUSY代数的表示形式，并讨论了其在Wess-Zumino模型中的最简单实现。为了有一个系统的方法得到超对称拉格朗日量，我们引入了超空间和超场的形式，并恢复了wesszumino拉格朗日量。然后将这些方法扩展到包括超对称阿贝尔和非阿贝尔规范理论与超物质耦合。由于超对称不是自然界的精确对称，它最终必须被打破。我们讨论了超对称性破断的几种机制(包括自发的和显式的)，并简要介绍了实现超对称性破断的各种建议。最后，我们构造了标准模型的最小超对称扩展(MSSM)，并考虑了对未来粒子物理中超对称性的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Anticipating the Next Discoveries in Particle Physics

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