Physics is written in mathematics, and at the base of mathematics lies distinction: yes or no, identical or different, one or zero. A bit is the minimal written form of such a distinction. Physics can therefore measure only what can become distinguishable. What cannot be distinguished cannot yet appear as a physical record. From distinguishability comes information; from the registration of information comes physical time. Unified informational Theory (UiT) presents a unified physical framework in which time, mass, force, thermodynamic directionality, electromagnetic coupling, nuclear structure, and horizon physics are expressed through one informational registration mechanism: closed phase becoming physical record. The central object is a closed-light phase carrier: a closed photon-like phase structure carrying informational increments of ℏ, rotating on a complex phase surface at the Compton frequency, with a Planck-scale phase radius. It is not treated as a point mechanically moving through ordinary three-dimensional space. Before measurement, its structure exists in the complex phase domain as physical distinguishability: real, active, and capable of producing measurable effects, but not yet written as an ordinary 3+1 record such as position, trajectory, detector event, clock reading, or linear-time history. Measurement is the operation that projects and registers part of this complex phase structure into ordinary record-space, using energy and carrying a thermodynamic cost. In UiT, linear physical time is the ordered registration of physical change into record. A record may be a clock reading, track, pointer state, detector click, environmental correlation, thermodynamic trace, or any stable physical mark. Time is not a passive background parameter. It is the informational order produced when phase structure becomes registered reality. The same principle also defines force. All forces are gradients of one underlying registration object, read under different load conditions, geometries, and coupling branches. A force appears where an invariant closed phase carrier is placed in a field whose time-registration rate varies across record-space. The carrier cannot change its own invariant Compton phase throughput, so the mismatch between invariant internal phase and local registration capacity becomes a physical force. Inertia and gravity are therefore not separate mysteries at the deepest level: both are responses of the same closed phase throughput to different ways of limiting temporal registration. Special relativity arises when recorded motion consumes part of the available registration bandwidth. Motion requires information about position and change of position, and this cost enters quadratically. The carrier phase itself never stops moving; what changes is how much of its invariant phase throughput can be written as linear time rather than as recorded motion. Lorentz time dilation is therefore read as a registration-budget partition: motion spends part of the time-writing capacity. Gravity arises from the same Compton throughput read radially. A mass is not merely an object placed inside space. It is closed-light Compton sampling of a Planck registration-stiffness update. Around it, record-space has reduced capacity to write distinguishable temporal information. Less capacity remains for writing time, and the radial gradient of that capacity is read as gravity. In this view, space is not a rubber sheet that literally bends. Space is the local capacity to register distinguishable physical alternatives. Changing the time-registration capacity also changes the spatial registration structure, so the same geodesics are obtained, but their ontology changes: curvature is the metric bookkeeping of variable registration capacity. This same capacity logic leads directly to thermodynamics and entropy. Entropy counts the available or dispersed ways in which distinctions can be written, stabilized, erased, hidden, or made inaccessible. Thermodynamic directionality is not added from outside. It is the cost and irreversibility of registering physical distinction into stable record. Horizon entropy is the saturated boundary count of the same closed phase surface: the point where ordinary exterior registration reaches its limiting boundary. Electromagnetism is read as a phase-connection branch of the same object. Charge is not introduced as an unrelated primitive substance, but as a coupling orientation of phase registration. Electric and magnetic effects are different record-space readouts of this phase connection under different motion and registration conditions. The weak sector gives UiT its primary empirical handle. Radioactive decay is treated as a finite identity-rewrite process. In order for a decay path to be environmentally perturbable, the environment must couple to degrees of freedom required for reverse daughter-to-parent reconstruction. This requires local reverse temporal registration: a limited branch in which identity is locally unwritten and rewritten. From this postulate, UiT produces a taxonomy of radioactive-decay perturbability, functioning like a periodic table of decay influence. The table does not merely classify known decays by name; it identifies which decay channels can be perturbed and why, according to the informational variables required by the reverse reconstruction path. The strong sector is expressed through closed multi-carrier phase geometry. Three phase carriers form a zero-sum closure in the complex plane. What appears outwardly as fractional charge is a projection of a deeper internal closure: one-third is externally read, while two-thirds remain internally locked within the phase structure. This gives a geometric and numerical account of fractional charge weights, confinement architecture, and the Cornell-potential structure, while leaving full QCD dynamics and detailed coefficients as completion targets. UiT is not presented as a theory of everything, and it does not discard established physics. It proposes a deeper informational primitive from which quantum phase, relativistic time, gravitational distortion, thermodynamic irreversibility, electromagnetic coupling, weak decay, strong closure, and horizon counting arise as different expressions of one closed phase-registration object. The empirical content is twofold. The primary tested layer is the weak-sector perturbability table, which organizes radioactive decay channels according to the informational degrees of freedom required for reverse daughter-to-parent reconstruction. A second prospective discriminant predicts photon arrival-time delay with no linear Planck-energy term and leading quadratic Planck suppression. The compact unification principle is this: physical law is the geometry of informational registration. Time is the written order of phase registration; mass is closed-light Compton throughput; force is the gradient of registration mismatch; entropy is the count and cost of distinguishable writing; and the apparent separation between relativity, thermodynamics, electromagnetism, nuclear structure, and horizon physics reflects different readout conditions of the same underlying closed phase surface.
yaniv riz (Sun,) studied this question.