We present a complete and rigorous formulation of the Quantum Geometric Emergence (QGE) theory, a background-independent framework in which both spacetime geometry and quantum matter fields are derived as low-energy, collective phenomena emerging from a more fundamental, discrete quantum relational network. The theory is built upon five core axioms, with its mathematical essence captured by a scale-dependent family of spectral triples, constructed from the category of finite-dimensional Hilbert spaces and quantum channels (QChan). The relational derivative operator is explicitly defined in terms of the entanglement structure of the network. We prove a key theorem: for a critical one-dimensional quantum Ising-type network, the spectral distance converges, under renormalization group flow, to the Euclidean distance on the real number line, providing a rigorous proof-of-principle for geometric emergence. Within this framework, gravity is reinterpreted as the dynamics of the network optimizing its global informational structure, naturally resolving the cosmological constant problem. We demonstrate how gauge fields (e.g., U(1)) and fermions can emerge from specific non-commutative substructures of the network algebra. The theory yields testable predictions, including characteristic non-Gaussianity in the CMB, Lorentz symmetry violation at high energies, and a novel explanation for dark matter as the imprint of network connectivity inhomogeneities. This work synthesizes and formalizes ideas introduced in two earlier preprints 1,2, establishing QGE as a concrete, mathematically defined candidate for a theory of quantum gravity.
Tao Zhou (Sat,) studied this question.
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