This paper presents a complete derivation of gravitational waves within the framework of Time Field Theory (TFT), a scalar theory of gravity based on the principle of metretike conservation. We demonstrate that gravitational waves arise naturally as fluctuations in the gradient of the time field, propagating at the speed of light to recalibrate the local time rate in response to changes in mass distribution. The key contribution of this work is the rigorous proof that gravitational waves in TFT must be exclusively quadrupole radiation with a single breathing polarization mode. This result is not an empirical fit but a mathematical necessity derived directly from the fundamental conservation laws of energy, momentum, and angular momentum. We clarify the critical distinction between the multipole order of the source (constrained by conservation laws) and the polarization mode of the wave (determined by the scalar nature of the field), resolving a common misconception about scalar gravitational theories. In the weak-field limit, TFT makes numerical predictions identical to General Relativity (GR) for all currently observed gravitational wave events. However, TFT provides a significantly shorter derivation chain, a more intuitive physical picture, and naturally resolves the century-old problem of the local definition of gravitational field energy, which remains unresolved in GR. We further discuss the testable differences between TFT and GR, most notably the prediction of a single scalar breathing polarization mode instead of the two tensor modes predicted by GR. This provides a clear and unambiguous experimental discriminant that can be tested by future gravitational wave detectors such as the Einstein Telescope and LISA. All currently observed gravitational wave events by the LIGO/Virgo/KAGRA network are fully compatible with the predictions of TFT.
Huowang Huang (Fri,) studied this question.