Kavli Institute for the Physics and Mathematics of the Universe
University of Tokyo
Researchers find way to show how the tiniest particles in our Universe saved us from complete annihilation
Recently discovered ripples of spacetime called gravitational waves could contain evidence to prove the theory that life survived the Big Bang because of a phase transition that allowed neutrino particles to reshuffle matter and anti-matter, explains a new study by an international team of researchers.
How we were saved from a complete annihilation is not a question in science fiction or a Hollywood movie. According to the Big Bang theory of modern cosmology, matter was created with an equal amount of anti-matter. If it had stayed that way, matter and anti-matter should have eventually met and annihilated one to one, leading up to a complete annihilation.
But our existence contradicts this theory. To overcome a complete annihilation, the Universe must have turned a small amount of anti-matter into matter creating an imbalance between them. The imbalance needed is only a part in a billion. But it has remained a complete mystery when and how the imbalance was created.
Fig 1: Inflation stretched the initial microscopic Universe to a macroscopic size and turned the cosmic energy into matter. However, it likely created an equal amount of matter and anti-matter predicting complete annihilation of our universe. The authors discuss the possibility that a phase transition after inflation led to a tiny imbalance between the amount of matter and anti-matter, so that some matter could survive a near-complete annihilation. Such a phase transition is likely to lead to a network of "rubber-band"-like objects called cosmic strings, that would produce ripples of space-time known as gravitational waves. These propagating waves can get through the hot and dense Universe and reach us today, 13.8 billion years after the phase transition. Such gravitational waves can most likely be discovered by current and future experiments. (Original credit: R. Hurt/Caltech-JPL, NASA, and ESA Credit: Kavli IPMU - Kavli IPMU modified this figure based on the image credited by R.Hurt/Caltech-JPL, NASA, and ESA)
“The Universe becomes opaque to light once we look back to around a million years after its birth. This makes the fundamental question of ‘why are we here?’ difficult to answer,” says paper co-author Jeff Dror, postdoctoral fellow at the University of California, Berkeley, and physics researcher at Lawrence Berkeley National Laboratory.
Since matter and anti-matter have the opposite electrical charges, they cannot turn into each other, unless they are electrical neutral. Neutrinos are the only electrical neutral matter particles we know, and they are the strongest contender to do this job. A theory many researchers support is that the Universe went through a phase transition so that neutrinos could reshuffle matter and anti-matter.
“A phase transition is like boiling water to vapor, or cooling water to ice. The behavior of matter changes at specific temperatures called critical temperature. When a certain metal is cooled to a low temperature, it loses electrical resistance completely by a phase transition, becoming a superconductor. It is the basis of Magnetic Resonance Imaging (MRI) for cancer diagnosis or maglev technology that floats a train so that it can run at 300 miles an hour without causing dizziness. Just like a superconductor, the phase transition in the early Universe may have created a very thin tube of magnetic fields called cosmic strings,” explains paper co-author Hitoshi Murayama, MacAdams Professor of Physics at the University of California, Berkeley, Principal Investigator at the Kavli Institute for the Physics and Mathematics of the Universe, University of Tokyo, and senior faculty scientist at Lawrence Berkeley National Laboratory.
Dror and Murayama are part of a team of researchers from Japan, US and Canada who believe the cosmic strings then try to simplify themselves, leading up to tiny wobbling of spacetime called gravitational waves. These could be detected by future space-borne observatories such as LISA, BBO (European Space Agency) or DECIGO (Japanese Astronautical Exploration Agency) for nearly all possible critical temperatures.
“The recent discovery of gravitational waves opens up a new opportunity to look back further to a time, as the Universe is transparent to gravity all the way back to the beginning. When the Universe might have been a trillion to a quadrillion times hotter than the hottest place in the Universe today, neutrinos are likely to have behaved in just the way we require to ensure our survival. We demonstrated that they probably also left behind a background of detectable gravitational ripples to let us know,” says paper co-author Graham White, a postdoctoral fellow at TRIUMF.
“Cosmic strings used to be popular as a way of creating small variations in mass densities that eventually became stars and galaxies, but it died because recent data excluded this idea. Now with our work, the idea comes back for a different reason. This is exciting!” says Takashi Hiramatsu, a postdoctoral fellow at the Institute for Cosmic Ray Research, University of Tokyo, which runs Japan’s gravitational wave detector KAGRA and Hyper-Kamiokande experiments.
“Gravitational wave from cosmic strings has a spectrum very different from astrophysical sources such as merger of black holes. It is quite plausible that we will be completely convinced the source is indeed cosmic strings,” says Kazunori Kohri, Associate Professor at the High Energy Accelerator Research Organization Theory Center in Japan.
“It would be really exciting to learn why we exist at all,” says Murayama. “This is the ultimate question in science.”
The paper was published as an Editor’s Suggestion in Physical Review Letters online on 28 January, 2020.
Journal: Physical Review Letters
Title: Testing Seesaw and Leptogenesis with Gravitational Waves
Authors: Jeff A. Dror(1, 2), Takashi Hiramatsu (3), Kazunori Kohri (4, 5, 6), Hitoshi Murayama (1, 6, 2, 7), and Graham White (8)
- Department of Physics, University of California, Berkeley, CA 94720, USA
- Ernest Orlando Lawrence Berkeley National Laboratory, Berkeley, CA 94720, USA
- Institute for Cosmic Ray Research, The University of Tokyo, Kashiwanoha 5-1-5, Kashiwa 277-8582, Japan
- Institute of Particle and Nuclear Studies, KEK, 1-1 Oho, Tsukuba 305-0801, Japan
- The Graduate University for Advanced Studies (SOKENDAI), 1-1 Oho, Tsukuba 305-0801, Japan
- Kavli Institute for the Physics and Mathematics of the Universe (WPI), University of Tokyo, Kashiwa 277-8583, Japan
- Deutsches Elektronen-Synchrotron DESY, Notkestrasse 85, 22607 Hamburg, Germany
- TRIUMF, 4004 Wesbrook Mall, Vancouver, BC V6T 2A3, Canada
DOI: 10.1103/PhysRevLett.124.041804 (Published January 28, 2020)
- Anti-matter was hypothesized by theoretical physicist and Nobel Laureate Paul Dirac, who came up with a theory of quantum mechanics that governs microscopic world of elementary particles, tried to combine his theory with Einstein’s theory of relativity that governs the macroscopic Universe. The anti-matter looks practically the same as matter, except that their electric charges are the opposite. If there is an ice cream cone made of anti-matter, it would look exactly the same until you grab it.
- The first anti-matter, the counterpart of electron called positron because of its positive charge, was discovered by Anderson in 1932 in aftermaths of high-energy particles, spewed out from ancient stellar explosions hitting the atmosphere.
- Researchers succeeded in creating an anti-proton in 1955 by bombarding accelerated proton hitting a target using a particle accelerator in Berkeley, led by Emilio Gino Segrè and Owen Chamberlain. To date, matter and anti-matter particles are created from energy always one to one.
- When matter and anti-matter meet, they annihilate back to energy one to one. If you grab an ice cream cone made of anti-matter, a part of you annihilate with the ice cream cone in a huge explosion, releasing much bigger energy than an atomic bomb.
- The idea that neutrinos are the best contender to tur a small amount of anti-matter into matter, creating an imbalance between them, originally proposed by Masataka Fukugita and Tsutomu Yanagida, both former researchers at the Kavli IPMU.
- Neutrinos are a very difficult particle to study, and the worldwide scientific community is on a race to see what it does and how it behaves. Billion-dollar projects called DUNE (Deep Underground Neutrino Experiment) and Hyper-Kamiokande (Kamioka Neutrino Detection Experiment) are in head-to-head competition to see how neutrinos and their anti-matter counter parts anti-neutrinos may behave differently from each other.
Kavli Institute for the Physics and Mathematics of the Universe
University of Tokyo