Dark matter, a mysterious and invisible substance, remains one of the most profound puzzles in modern astrophysics. Despite being undetectable by conventional means, its presence is inferred through its gravitational effects on visible matter, radiation, and the large-scale structure of the universe. Comprising roughly 27% of the universe's total mass-energy content, dark matter far outweighs the ordinary matter that makes up stars, planets, and galaxies. However, scientists have yet to identify its true nature.

The origins of the dark matter hypothesis trace back to the early 20th century when astronomers noticed an unusual phenomenon. The visible mass of galaxies and clusters of galaxies appeared insufficient to explain their observed gravitational behavior. In the 1930s, Swiss astronomer Fritz Zwicky first coined the term “dark matter” while studying galaxy clusters. He realized that the galaxies within these clusters were moving too quickly for the amount of visible matter present, suggesting the existence of an unseen mass exerting a gravitational pull. Since then, dark matter has become an essential concept for understanding the dynamics of galaxies and the larger structure of the universe.

Over the decades, further evidence for dark matter has emerged, from the rotation curves of galaxies to the behavior of galaxy clusters. When astronomers measure how fast stars orbit the center of a galaxy, they find that stars on the outer edges move much faster than expected based on the mass visible in the galaxy. If only the observed matter were present, the stars would not have enough gravitational pull to remain bound to the galaxy. This discrepancy is explained by the presence of an unseen mass-dark matter-scattered throughout the galaxy. Additionally, observations of the cosmic microwave background radiation, which reflects the early universe, also point to dark matter's existence as a key player in the formation of the cosmos.