What question did this study set out to answer?

This work aims to define the spinor structure related to hyperbolic clifford algebra and its implications in theoretical physics.

April 16, 2026Open Access

On the Geometric Structure of Hyperbolic Clifford Bundles and Associated Spin Groups

Key Points

This work aims to define the spinor structure related to hyperbolic clifford algebra and its implications in theoretical physics.
Presented the spinor structure linked to hyperbolic clifford algebra ClHV.
Defined orthogonal groups and transformations associated with hyperbolic space HV.
Introduced the Clifford–Lipschitz group and defined associated Pin and Spin groups.
Derived the frame bundle and spinor structure related to hyperbolic clifford algebra.
Established ClHV as a unified framework for multiforms and multivectors.
Provided a natural setting for analyzing superfields in theoretical physics.
Defined new mathematical structures aiding in the understanding of gravitational theories.

Abstract

In this paper, we present the spinor structure associated with the Hyperbolic Clifford algebra of a real n-dimensional vector space V, which is denoted by ClHV. Unlike the standard Clifford algebra, the Hyperbolic Clifford algebra Cl(HV) simultaneously accommodates both multiforms and multivectors in a single algebraic structure, making it the natural framework—known as the “mother algebra”—for the study of superfields in theoretical physics and for generalizing the Clifford bundle formalism to hyperbolic structures arising in gravitational theories. The orthogonal groups and orthogonal transformations associated to the hyperbolic space HV are presented. The Clifford–Lipschitz group and the Pin and Spin groups associated with ClHV are defined. Then, the frame bundle and spinor structure associated to Hyperbolic Clifford algebra is derived.

On the Geometric Structure of Hyperbolic Clifford Bundles and Associated Spin Groups

Key Points

Abstract

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