Dark energy, responsible for the accelerated expansion of the universe, is one of the greatest mysteries in modern cosmology. The standard \ (\) CDM model treats it as a cosmological constant, but this leaves the “cosmological constant problem” unresolved and predicts a constant equation of state that may be in tension with observations. This paper develops an interpretation within Energy-Efficiency Theory (EET). Starting from **Yang’s Axioms** 1, we propose that dark energy is not a constant but the cosmic-scale gradient of free-state energy—the spatial inhomogeneity of the vacuum’s lowest-energy background. As the universe expands, the free-state background is stretched, creating a gradient that acts as a repulsive gravitational source. We derive the Friedmann equations from EET principles, showing how the free-state gradient generates acceleration, and connect to the observed distance-redshift relation. The framework quantitatively recovers the Hubble constant \ (H₀ = 71. 51. 2\) km/s/Mpc, the CMB power spectrum, and the BAO scale, resolving the Hubble tension. We provide a rigorous proof of the dark energy–matter coupling from energy-momentum conservation, with coupling strength \ (g = 1. 210^-3\). Testable predictions include a specific redshift-dependent equation of state \ (w (z) = -1 + (1+z) \) with \ (0. 1\), a novel scaling law for the free-state energy fraction, and a distinct evolution of the acceleration rate. We extend the framework to extreme regimes: early universe, high-redshift quasars, and the ultimate fate of the cosmos. The framework is fully compatible with general relativity at large scales while providing a first-principles ontology for dark energy.
Hongpu Yang (Thu,) studied this question.