In the vast realm of particle physics, one of the most intriguing and elusive particles is the neutrino. The discovery of neutrinos revolutionized our understanding of the fundamental building blocks of the universe. In this subchapter, we delve into the captivating story behind the detection and characterization of these mysterious particles. The journey to unravel the secrets of neutrinos began in the early 20th century. In 1930, physicist Wolfgang Pauli proposed the existence of a neutral particle that could explain the missing energy and momentum in certain radioactive decays. Pauli named this hypothetical particle the "neutrino," which means "little neutral one" in Italian. Years later, in 1956, the first experimental evidence for neutrinos emerged. A team of scientists led by Clyde Cowan and Frederick Reines conducted the famous neutrino detection experiment at the Savannah River nuclear reactor in South Carolina. This innovative experiment involved observing the interaction between neutrinos and protons, resulting in the detection of electron antineutrinos. Cowan and Reines' groundbreaking work confirmed the existence of neutrinos and earned them the Nobel Prize in Physics in 1995. Since then, numerous experiments have expanded our knowledge of neutrinos. These elusive particles come in three flavors: electron, muon, and tau neutrinos. They possess minuscule masses, making them difficult to detect and study. However, their intriguing properties have captivated scientists worldwide. Neutrinos have played a crucial role in unraveling the mysteries of the universe. They are produced in various astrophysical phenomena, such as supernovae and black holes, and carry valuable information about these cosmic events. Moreover, neutrinos have been instrumental in understanding the phenomenon of neutrino oscillation, whereby they change from one flavor to another as they travel through space. The study of neutrinos has also led to profound implications beyond particle physics. Neutrino experiments have shed light on the nature of matter and antimatter asymmetry in the universe. Furthermore, they have provided insights into the fundamental properties of neutrinos, such as their masses and mixing angles. As we delve deeper into the intricacies of neutrino physics, we unlock new frontiers and pave the way for groundbreaking discoveries. From neutrino telescopes buried deep underground to detectors submerged in vast bodies of water, scientists continue to push the boundaries of our knowledge. The study of neutrinos promises to unravel the secrets of the universe and revolutionize our understanding of particle physics.