Spin(11, 3), particles, and octonions

Krasnov, Kirill

doi:10.1063/5.0070058

Cited by 9 publications

(6 citation statements)

References 32 publications

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Section: Introductionmentioning

confidence: 91%

“…Nesti & Percacci [58] and Krasnov [59] have previously proposed that Spin (10) and the Lorentz group Spin (3,1) are unified in Spin (11,3), and that the 64 spinors of a generation comprise one of the two chiral components of the 2 7 = 128 spinors of Spin (11,3). The 64 spinors comprise 32 spinors that are direct products of right-handed Spin (10) spinors with right-handed Dirac spinors, and their 32 antispinor conjugate partners that are direct products of left-handed Spin (10) spinors with left-handed Dirac spinors.…”

Section: Spin(113)mentioning

confidence: 99%

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Unification of the four forces in the Spin(11,1) geometric algebra

Hamilton¹

2023

Phys. Scr.

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SO(10), or equivalently its covering group Spin(10), is a well-known promising grand unified group that contains the standard-model group. The spinors of the group Spin(N) of rotations in N spacetime dimensions are indexed by a bitcode with [N/2] bits. Fermions in Spin(10) are described by five bits yzrgb, consisting of two weak bits y and z, and three colour bits r, g, b. If a sixth bit t is added, necessary to accommodate a time dimension, then the enlarged Spin(11,1) algebra contains the standard-model and Dirac algebras as commuting subalgebras, unifying the four forces. The symmetry breaking chain that breaks Spin(11,1) to the standard model appears to be essentially unique, proceeding via the Pati-Salam group. The Higgs sector appears similarly unique, consisting of the dimension~66 adjoint representation of Spin(11,1); in effect, the scalar Higgs sector matches the vector gauge sector. Although the unified algebra is that of Spin(11,1), the persistence of the electroweak Higgs field after grand symmetry breaking suggests that the gauge group before grand symmetry breaking is Spin(10,1), not the full group Spin(11,1). The running of coupling parameters predicts that the standard model should unify to the Pati-Salam group Spin(4)_w times Spin(6)_c at 10^{12} GeV, and thence to Spin(10,1) at 10^{15} GeV. The grand Higgs field breaks t-symmetry, can drive cosmological inflation, and generates a large Majorana mass for the right-handed neutrino by flipping its t-bit. The electroweak Higgs field breaks y-symmetry, and generates masses for fermions by flipping their y-bit.

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Section: Introductionmentioning

confidence: 91%

Section: Spin(113)mentioning

confidence: 99%

Unification of the four forces in the Spin(11,1) geometric algebra

Hamilton¹

2023

Phys. Scr.

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“…Inspired by [24,46,63], we shall display and discuss the symmetry subalgebras of C n , n = 8, 9, 10 of the complex structure generated by the Clifford pseudoscalar ω R 6 corresponding to the right action of the octonions:…”

Section: Complex Structure Associated With R 7 : a Commentmentioning

confidence: 99%

Octonion Internal Space Algebra for the Standard Model

Todorov

2023

Universe

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This paper surveys recent progress in our search for an appropriate internal space algebra for the standard model (SM) of particle physics. After a brief review of the existing approaches, we start with the Clifford algebras involving operators of left multiplication by octonions. A central role is played by a distinguished complex structure that implements the splitting of the octonions O=C⊕C3, which reflect the lepton-quark symmetry. Such a complex structure on the 32-dimensional space S of Cℓ10 Majorana spinors is generated by the Cℓ6(⊂Cℓ10) volume form, ω6=γ1⋯γ6, and is left invariant by the Pati–Salam subgroup of Spin(10), GPS=Spin(4)×Spin(6)/Z2. While the Spin(10) invariant volume form ω10=γ1…γ10 of Cℓ10 is known to split S on a complex basis into left and right chiral (semi)spinors, P=12(1−iω6) is interpreted as the projector on the 16-dimensional particle subspace (which annihilates the antiparticles).The standard model gauge group appears as the subgroup of GPS that preserves the sterile neutrino (which is identified with the Fock vacuum). The Z2-graded internal space algebra A is then included in the projected tensor product A⊂PCℓ10P=Cℓ4⊗Cℓ60. The Higgs field appears as the scalar term of a superconnection, an element of the odd part Cℓ41 of the first factor. The fact that the projection of Cℓ10 only involves the even part Cℓ60 of the second factor guarantees that the color symmetry remains unbroken. As an application, we express the ratio mHmW of the Higgs to the W boson masses in terms of the cosine of the theoretical Weinberg angle.

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“…More detailed investigations of the proposed model can include, for example, the study of the lepto-quark mixing with an eye on realistic mass hierarchies and new sources of charge-parity violation, as well as the physics connected with the seven-sphere manifold [20][21][22] and its implication for octonionic description of elementary particles [23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Unification based on the mysterious cubic-structure grouping of quarks and leptons

Mehrafarin

2023

Phys. Scr.

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We present a unification model based on the well-known but mysterious cubic-structure grouping of quarks and leptons that suggests an underlying symmetry connection deemed explainable by a unified theory. It results in an extension of the Pati-Salam model that consolidates the fermions into two sixteen-dimensional chiral representations of the gauge group. Moreover, the discrete cubic flavor symmetry arbitrarily conjectured in the literature is found here to be implied by the gauge symmetry. Furthermore, the gauge algebra also describes an eleven-dimensional spacetime decomposed into the usual spacetime and the seven-sphere, which is the manifold of unit octonions. This suggests such a spacetime is apt for embracing all elementary particles and their interactions, relevant to an underlying M-theory description.

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Spin(11, 3), particles, and octonions

Cited by 9 publications

References 32 publications

Unification of the four forces in the Spin(11,1) geometric algebra

Unification of the four forces in the Spin(11,1) geometric algebra

Octonion Internal Space Algebra for the Standard Model

Unification based on the mysterious cubic-structure grouping of quarks and leptons

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