Spacetime, gravity, and cosmology are traditionally treated as fundamental ingredients of physical theory. In this work, we present a framework in which spacetime instead arises as a condensed phase of a deeper, non-geometric system composed of strand-like degrees of freedom. A tachyonic instability drives condensation, suppressing microscopic vibrational motion and producing a frozen, disordered node–edge network. Geometry emerges as a coarse-grained descriptor of the network’s collective response, while gravitational dynamics correspond to transverse–traceless shear modes that survive disorder and dominate the infrared behavior, reproducing general relativity as a universality class rather than a fundamental postulate. Within this structural-realist picture, spacetime, time, and matter are not independent ontological elements but distinct manifestations of the same condensed medium. Localized, stable, finite-extent excitations of the frozen network arise generically in a disordered phase and provide a mechanical basis for particle-like behavior, inertia, and localization without introducing independent matter fields. Matter is thus interpreted as defect-like excitations embedded within the same medium whose bulk response defines the emergent metric, ensuring universal coupling to gravity at leading order. The Planck scale is reinterpreted as a critical strain threshold at which the condensed spacetime phase fails, rather than as a fundamental ultraviolet cutoff. Black holes correspond to regions of spacetime melting bounded by high-entropy interfaces, replacing curvature singularities with physical phase boundaries and allowing information to be preserved through transfer to the underlying substrate. Cosmological features such as inflation, large-scale homogeneity, and late-time acceleration are interpreted as consequences of global condensation, phase ordering, and residual relaxation of the condensed phase. The framework is intentionally conservative and phenomenological. It does not attempt a complete derivation of Standard Model structure, but instead establishes minimal structural constraints under which universality, inertia, localization, and geodesic motion are unavoidable consequences of a single condensed phase. The theory is falsifiable in principle through deviations from Einsteinian behavior under extreme strain, modifications to high-frequency gravitational wave propagation, or breakdowns of universality near the condensation failure scale. Overall, the work offers a unified physical picture in which spacetime is emergent, metastable, physically instantiated, and subject to failure under extreme conditions.
Jerad Happe (Fri,) studied this question.