Neutrino Mass and the KATRIN Experiment

Neutrino Mass and the KATRIN Experiment Latest News

The latest update from the KATRIN experiment has brought significant advancement in particle physics.

What are Neutrinos?

• Neutrinos are electrically neutral subatomic particles that are produced in processes like radioactive decay and nuclear reactions, including those occurring in the sun and stars.
• They are one of the fundamental particles in the Standard Model of particle physics, but their mass remains unknown.
• Unlike other fundamental particles, neutrinos are extremely lightweight, with masses less than a millionth that of an electron.

What is the KATRIN Experiment?

• KATRIN stands for Karlsruhe Tritium Neutrino experiment, and it is located in Karlsruhe, Germany.
• Its primary aim is to precisely measure the mass of the electron antineutrino, a type of neutrino produced in beta decay.
• The experiment focuses on studying the decay of tritium, a radioactive isotope of hydrogen, which emits both an electron and an electron antineutrino.
• The energy of the emitted electron is affected by the mass of the neutrino — hence, measuring electron energies helps infer the upper limit of the neutrino’s mass.

Recent Findings

• In its latest analysis, KATRIN has reduced the upper limit of the neutrino mass to less than 0.45 electron volts (eV).
• This is a significant improvement over its earlier result and represents a nearly 50% reduction in the previously estimated maximum value.
• The data is based on the precise measurement of energies from 36 million electrons produced in tritium decay.

Neutrino Mass and the KATRIN Experiment FAQs

Q1. What are neutrinos?
Ans. Electrically neutral subatomic particles with minuscule mass, categorized into three “flavors”: electron, muon, and tau.

Q2. Why is measuring neutrino mass crucial?
Ans. It impacts cosmology (dark matter/dark energy) and particle physics (Beyond Standard Model theories).

Q3. How does KATRIN work?
Ans. The Karlsruhe Tritium Neutrino Experiment (Germany) measures tritium beta decay to determine neutrino mass, achieving a sensitivity of 0.2 eV/c².

Q4. How is India contributing to neutrino research?
Ans. Through the proposed India-based Neutrino Observatory (INO), focusing on atmospheric neutrino studies in Tamil Nadu.

Source: SCN