Reconciling quantum mechanics with general relativity remains the central unsolved problem of fundamental physics. This paper develops the Medium–Sensor Framework (MSF), a conceptual framework that reframes the unification problem not as the merger of two incompatible mathematical formalisms but as the recognition of a functional complementarity between two operational layers of a single system. Quantum mechanics describes the Medium — the fundamental, discrete, probabilistic substrate in which energy, information, and movement reside — while gravity is reinterpreted as an emergent Sensor: a coarse-grained, relational readout that translates the state of the Medium into the geometry of spacetime. The two layers are connected by a proposed scale-invariant dynamical loop built from the triad of Energy, Information, and Movement (E–I–M). An operator formulation based on the Heisenberg equation of motion is augmented by a dissipative term tied to the Gorini–Kossakowski–Sudarshan–Lindblad generator of open-system dynamics. The resulting field equation is shown to be a special case of scalar–tensor gravity, with the information field as a non-minimally coupled scalar, and on that basis a candidate action principle is proposed that renders the theory generally covariant and its conservation laws automatic. This yields a falsifiable prediction: a single coupling governs both the post-Newtonian deviation measured in the solar system and the maximum dark-energy deviation observable cosmologically, so that a robust detection of evolving dark energy beyond a computable ceiling, with solar-system gravity still bounded, would falsify the minimal theory. The framework is situated within the literature on emergent and entropic gravity, holography, loop quantum gravity, and decoherence theory, and eight observational arenas are presented as testing grounds for its claims.
Juan Matias Schüttenberg (Sat,) studied this question.