Physicists have developed a novel method to investigate dark matter using gravitational wave detectors, potentially uncovering the effects of dark matter particles on neutron stars. This approach offers new insights into dark matter, extending beyond the reach of current detectors and paving the way for future discoveries with advanced gravitational wave observatories.
Dark matter is fundamental to our understanding of the Universe, yet its exact nature remains a mystery. Uncovering the identity of dark matter is a crucial objective in cosmology and particle physics.
A collaborative effort by physicists from the Tata Institute of Fundamental Research, the Indian Institute for Science, and the University of California at Berkeley has introduced a novel method to investigate dark matter. This method utilizes gravitational wave searches to detect dark matter’s potential effects on neutron stars.
New Methodology Explained
Sulagna Bhattacharya, a graduate student at TIFR and lead author of the study published in Physical Review LettersPhysical Review Letters (PRL) is a peer-reviewed scientific journal published by the American Physical Society. It is one of the most prestigious and influential journals in physics, with a high impact factor and a reputation for publishing groundbreaking research in all areas of physics, from particle physics to condensed matter physics and beyond. PRL is known for its rigorous standards and short article format, with a maximum length of four pages, making it an important venue for rapid communication of new findings and ideas in the physics community.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>Physical Review Letters, explains — dark matter particles in the galaxy can accumulate in neutron stars due to their non-gravitational interactions. The accumulated particles form a dense core, that collapses to a minuscule black holeA black hole is a place in space where the gravitational field is so strong that not even light can escape it. Astronomers classify black holes into three categories by size: miniature, stellar, and supermassive black holes. Miniature black holes could have a mass smaller than our Sun and supermassive black holes could have a mass equivalent to billions of our Sun.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>black hole in the scenario that dark matter particle is heavy and has no antiparticle counterpart; a scenario that has proved difficult to test otherwise in laboratory experiments.
For a large allowed range of dark matter particle mass, the initial seed black hole consumes its host neutron starA neutron star is the collapsed core of a large (between 10 and 29 solar masses) star. Neutron stars are the smallest and densest stars known to exist. Though neutron stars typically have a radius on the order of just 10 – 20 kilometers (6 – 12 miles), they can have masses of about 1.3 – 2.5 that of the Sun.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>neutron star and transmutes it to a neutron-star-mass black hole. Crucially, theories of stellar evolution predict that black holes form when neutron stars exceed about 2.5 times the mass of the Sun, as encoded in the Tolman-Oppenheimer-Volkoff limit, but here dark matter leads to low-mass black holes that are typically smaller than the maximal neutron star.
Gravitational wave detectors as probes of dark matter graphic. Credit: Basudeb Dasgupta
Anupam Ray, who co-led the work, points out that “for dark matter parameters that are not yet ruled out by any other experiment, old binary neutron star systems in dense regions of the galaxy ought to have evolved into binary black hole systems. If we do not see any anomalously low-mass mergers, it puts new constraints on dark matter.”
Linking Dark Matter and Black Holes
Intriguingly, some of the events detected by LIGOThe Laser Interferometer Gravitational-Wave Observatory (LIGO) is a large-scale physics experiment and observatory supported by the National Science Foundation and operated by Caltech and MIT. It's designed to detect cosmic gravitational waves and to develop gravitational-wave observations as an astronomical tool. It's multi-kilometer-scale gravitational wave detectors use laser interferometry to measure the minute ripples in space-time caused by passing gravitational waves. It consists of two widely separated interferometers within the United States—one in Hanford, Washington and the other in Livingston, Louisiana.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>LIGO, e.g., GW190814 and GW190425, appear to involve at least one low-mass compact object. A tantalizing suggestion, based on pioneering work by Hawking and Zeldovich from the 1960s, is that low-mass black holes could be of a primordial origin, i.e., created by exceedingly rare but large density fluctuations in the very early universe.
Motivated by these considerations, the LIGO collaboration has undertaken targeted searches for low-mass black holes and set limits. The present study by Bhattacharya and collaborators shows that the same non-detection of low-mass mergers by LIGO also puts stringent constraints on particle dark matter.
The constraints presented in this study hold significant value, as they explore parameter space that is well beyond the reach of the current terrestrial dark matter detectors like XENON1T, PANDA, LUX-ZEPLIN, especially for heavy dark matter particles.
Future of Gravitational Wave Observations
Mergers of low-mass black holes are expected to be detectable not only using existing gravitational wave detectors such as LIGO, VIRGO, and KAGRA, but also by upcoming detectors like Advanced LIGO, Cosmic Explorer, and the Einstein Telescope. By considering the planned upgrades of current gravitational wave experiments, and accounting for their increased sensitivity and observation time, the study forecasts the constraints that could be obtained within the next decade.
In particular, the study shows, that gravitational wave observations can probe extremely feeble interactions of heavy dark matter, well below the so-called “neutrino floor” where conventional dark matter detectors have to contend with the astrophysical neutrino backgrounds.
Instead, if exotic low-mass black holes are discovered in the future, it could be a valuable hint about the nature of dark matter. The authors sign off optimistically noting, “gravitational wave detectors, which have already proved useful for the direct detection of black holes and gravitational wavesGravitational waves are distortions or ripples in the fabric of space and time. They were first detected in 2015 by the Advanced LIGO detectors and are produced by catastrophic events such as colliding black holes, supernovae, or merging neutron stars.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>gravitational waves predicted by Einstein, may end up as a powerful tool to test theories of dark matter as well.”
Reference: “Can LIGO Detect Nonannihilating Dark Matter?” by Sulagna Bhattacharya, Basudeb Dasgupta, Ranjan Laha and Anupam Ray, 29 August 2023, Physical Review Letters.
DOI: 10.1103/PhysRevLett.131.091401
The study was funded by the Department of Atomic Energy (Government of India), the Department of Science and Technology (Government of India) through a Swarnajayanti Fellowship, the Max-Planck- Gesellschaft through a Max Planck Partner Group, the Indian Institute of Science, Bengaluru, the Department of Science and Technology (Government of India), the National Science Foundation, the Heising-Simons Foundation, and the Infosys Foundation (Bengaluru).
Source: SciTechDaily
