Deformations of Jordan Algebras via the Jordan Defect: An Explicit Low--Degree Deformation Complex

Abstract

Over a field of characteristic 0 we give a concrete, computation--ready description of Jordan algebra structures and their low--order deformation theory. The Jordan identity is quartic in the elements and cubic in the multiplication, and in characteristic 0 it is equivalent to its standard four--variable polarization. We encode this polarization as a cubic map in the product~μ, called the Jordan defect J(μ). Linearizing this defect yields an explicit low--degree deformation complex \[ C1(J)\;δμ\; C2(J)\;dμ\; C3(J), \] whose second cohomology classifies infinitesimal deformations modulo equivalence and whose obstruction space \[ Obs3μ := C3(J)/im(dμ) \] contains the primary obstruction to extending such deformations. We emphasize that this construction captures only the low--degree part of the operadic deformation theory and does not claim to produce the full governing L∞ structure.

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