A Phase-Based Interpretation of Physical Phenomena from Space Vibration Without Fundamental Time

We present a phenomenological framework in which physical phenomena are described as phase manifestations of an underlying space-vibration field.In this approach, space is not treated as a fixed geometric background but as a persistent vibration state that exists even in vacuum conditions without dissipation. Energy, matter, radiation, and gravitational effects are interpreted as emergent structures arising from distinct phase configurations of this vibration field.The formulation does not assume time as a fundamental physical entity; instead, temporal parameters appear only as auxiliary variables introduced for effective descriptions of ordered phase transitions. Within this framework, black holes are reinterpreted as vibration-free phases in which spatial degrees of freedom become undefined.This perspective provides an alternative conceptual interpretation of infinite-density descriptions and singular behavior without invoking breakdowns of physical law. A minimal mathematical representation is introduced to illustrate the internal consistency of the framework.Connections to established results in relativistic and quantum physics are discussed, and potential observational consequences in strong-gravity and vacuum regimes are outlined. The present work is intended as a conceptual and phenomenological reformulation rather than a complete fundamental theory.Its purpose is to clarify foundational assumptions and to provide a unified interpretative structure for further theoretical and empirical investigation.