Abstract In a theory in which spacetime is understood not as a fundamental prerequisite but as an emergent macroscopic structure, physical dynamics cannot simply be introduced as an independent fundamental postulate. Concepts such as temporal evolution, field equations, and motion ordinarily presuppose a spacetime structure within which they are defined. If, however, a stable emergent spacetime phase has already been operationally identified, the further question arises: what form of macroscopic dynamics is admissible within such a phase under minimal structural assumptions? This work examines that question through the linear response of collective degrees of freedom around stable, homogeneous, and isotropic background configurations. The starting point is not an additional kinematic structure, a fundamental time variable, or a presupposed field model, but the second variation of a trace-invariant relational action. From this local stability and response structure, one obtains the effective operator that describes the admissible collective fluctuations in the infrared regime. It is shown that the conditions of a stable emergent spacetime phase impose a structural constraint on the form of this effective response operator. In the collective sector, the operator is fixed, up to normalization and admissible projections, by the linearized stability structure and assumes a Laplace-like normal form. Macroscopic dynamics therefore does not enter as an additional postulate; rather, it follows from the structural conditions required for a spacetime phase to be stable and operationally accessible. The spectral properties of this operator provide the operational basis for infrared modes, effective scalings, dispersion relations, and consistency diagnostics such as spectral dimension and stability windows. These quantities are not introduced as independent physical assumptions, but are interpreted as different representations of the same linear response structure. Correspondingly, deviations from the Laplace-like infrared normal form indicate not merely model failure, but the violation of at least one of the presupposed structural conditions. The analysis thereby establishes the status of macroscopic dynamics within emergent spacetime: dynamics is not postulated as fundamental, but arises as the structurally constrained linear response of a stable spacetime phase. Its scope remains restricted to the infrared, collective, and linearly stabilized regime; within this scope, however, it is not arbitrary, but fixed by the underlying spacetime structure.
Jan Ercan Gültekin (Thu,) studied this question.