麻豆淫院

A group of physicists, three with Harvard University's Department of 麻豆淫院ics and Laboratory for Particle 麻豆淫院ics and Cosmology, and the fourth with the University of Liverpool, has found evidence suggesting that additional measurements of neutrinos generated in Earth's atmosphere could be used to reveal how the three types of neutrino masses are ordered.

In their paper in the journal 麻豆淫院ical Review X, C. A. Arg眉elles, I. Mart铆nez-Soler, M. Jin and P Fern谩ndez, describe how they conducted an analysis of the expected sensitivities of current and near-future water/ice-Cherenkov atmospheric neutrino experiments as they may relate to the three types of neutrino oscillations.

Josh Spitz, a physicist at the University of Michigan, has published a in Nature outlining the work done by the team on this new effort.

Neutrinos are sub-atomic particles, and there are three known varieties; electron-neutrino, muon-neutrino, and tau-neutrino鈥攊ts type is believed to be set when it is created. Neutrinos can be created in a variety of ways, such as during a supernova or other major astral event. Interestingly, they can also change from one type to another, for example when they pass through a planet. Such a changes is known as quantum mixing.

Scientists have been studying neutrinos with the hope that doing so will help to unlock some of the big mysteries that remain in physics, such as the nature of gravity and dark matter. As the team on this new effort notes, developing ways to more precisely measure neutrinos would lead toward a better understanding of how mixing works. One goal is to determine the masses of the three types of neutrinos.

麻豆淫院icists study neutrinos in a variety of ways, such as by generating them using particle accelerator colliders, by observing them in nature, and by studying the means by which they are generated in Earth's atmosphere when cosmic rays collide with atmospheric atoms. It is on this third method that the research team has focused their efforts.

Current efforts to study such neutrinos typically involve building water or ice chambers with photodetectors sensitive enough to capture neutrinos as they collide with atoms in the tank. By studying the light pattern emitted during such collisions, researchers can determine the type of neutrino involved, its energy level and how far it traveled before the collision occurred.

By analyzing a large sample of such collisions and the data they have revealed thus far, the research team found that information is amassing a rate that should allow for determining the masses of the three types of neutrinos by the year 2030.