Abstract

The study of wave phenomena has fascinated researchers for centuries, yet a comprehensive and fundamental understanding of waves remains elusive. In this research, we embark on a scientific journey to provide a definitive definition of waves and explore how the universe's expansion played a crucial role in this significant intellectual discovery. We begin by investigating light as an unchanging temporal reference point free from temporal properties. We examine the role of light as an essential tool for cosmological observations and its intricate connection to waveparticle duality. This exploration reveals intriguing contradictions that arise when attributing wave-like characteristics to particles. Continuing our investigation, we delve into the temporal anomalies experienced near black holes, where time comes to a standstill. This inquiry sheds light on the consequences of temporal cessation and the effects on individuals within these cosmic phenomena. Furthermore, we scrutinize the transition from photon emission to time dilation, drawing parallels between energy quantization and the spatiotemporal acceleration of electrons. Our analysis extends to the four-dimensional framework and employs rigorous methodologies to comprehend the complexities of space-time dynamics. Ultimately, we emphasize the profound significance of "Altansiq Alzamani," the concept denoting temporal alignment, in unraveling the intricate interrelationships among cosmic entities. This compelling argument sparks contemplation of the quantized nature of charge fields and their potential for advancing our understanding of electron behavior. This paper prepares to embark on a captivating scientific exploration into the depths of wave phenomena and cosmic dynamics, expanding our knowledge and paving the way for further advancements in this fascinating field.