10.8. Qcd-Gravity duality | quantum gravity mechanism
Why is the QCD coupling strength vastly stronger than gravity in gauge-gravity duality?
A fundamental duality emerges between the SU(3)-driven compression of matter at quantum scales and the emergent gravitational field: The mass of hadrons arises from intense color-force compaction within subnuclear volumes, whereas gravity manifests as the coherent stretching of the finite space elementary quanta (SEQ) fabric. This stark contrast in interaction ranges—from quark confinement to system-wide SEQ deformation—naturally explains the hierarchical strength difference between nuclear and gravitational forces.
In simple terms, the elastic coefficients and deformation ratios differ between the compressive phase (QCD) and the tensile phase (gravity). The deformation of gravity is distributed across the entire space, whereas QCD's deformation is highly localized. This difference leads to the distinct energy scales of QCD and gravity. Different deformation ratios lead to different strengths.
