The most abundant element in the universe is hydrogen. Hydrogen makes up about 75% of the mass of the observable universe. This is because hydrogen is the simplest and lightest element, consisting of only one proton and one electron, and is the primary building block for all other elements.

The prevalence of hydrogen as the most abundant element in the universe is not only a testament to its simplicity and lightness but also a key factor in the fundamental processes that shape the cosmos. Beyond its role as the primary building block for other elements, hydrogen plays crucial roles in various astrophysical phenomena and cosmic evolution.

1. **Cosmic Nucleosynthesis:** Hydrogen's dominance in the universe is linked to the early moments after the Big Bang. During the first few minutes of the universe's existence, conditions were extremely hot and dense. During this period, known as primordial nucleosynthesis, hydrogen nuclei (protons) fused to form helium nuclei. The abundance of hydrogen during this phase set the stage for the subsequent formation of stars.

2. **Star Formation:** Hydrogen is the primary fuel for stellar nucleosynthesis. In the cores of stars, where temperatures and pressures are extremely high, hydrogen undergoes nuclear fusion, converting hydrogen nuclei into helium through a process known as stellar hydrogen burning. This process releases vast amounts of energy and is the source of starlight.

3. **Main Sequence Stars:** The majority of stars in the universe, including our sun, are classified as main sequence stars, where hydrogen fusion in their cores is the primary energy source. During this phase, hydrogen is continuously converted into helium through nuclear fusion, releasing energy in the form of light and heat. This process sustains the star for most of its lifetime.

4. **Supernovae and Element Formation:** The life cycle of a massive star culminates in a supernova explosion, where heavier elements are formed through nucleosynthesis. The explosion disperses these newly synthesized elements into space, enriching the interstellar medium with elements beyond hydrogen and helium. Thus, hydrogen not only forms the basis of stars but also contributes to the creation of heavier elements that make up planets, moons, and other celestial bodies.

5. **Cosmic Microwave Background Radiation:** The abundance of hydrogen during the early universe also left an imprint on the cosmic microwave background (CMB) radiation. The CMB is the faint glow of radiation left over from the Big Bang. The composition of hydrogen and helium during the early universe influences the characteristics of the CMB observed today.

6. **Interstellar Medium:** In the vast spaces between stars, the interstellar medium consists largely of hydrogen in various states, including molecular hydrogen (H2) and atomic hydrogen (H I). These regions serve as the birthplaces of new stars and planetary systems, as gravitational forces cause hydrogen gas clouds to collapse and form stellar nurseries.

7. **Cosmic Filaments and Large-Scale Structure:** Hydrogen is a key component in the large-scale structure of the universe. It forms vast cosmic filaments and sheets, creating a cosmic web that delineates the distribution of matter on the largest scales. These structures influence the gravitational interactions between galaxies and galaxy clusters.

8. **Dark Matter Search:** Hydrogen is also instrumental in ongoing astronomical efforts to study dark matter. Observations of hydrogen clouds in galaxies help astronomers map the distribution of visible matter, providing clues about the presence and distribution of dark matter, which remains one of the mysteries of the universe.

In essence, the abundance of hydrogen shapes the dynamics and evolution of the universe, from the early moments after the Big Bang to the ongoing processes within stars and the vast cosmic structures that define the cosmos. Hydrogen's simplicity and ubiquity make it a foundational element in our understanding of the cosmos.