Dr. Avi Loeb, Frank B. Baird Jr. Professor of Science at Harvard, and
Amir Siraj, a Harvard undergraduate student, have developed the new
method to search for black holes in the outer solar system, based on
flares that result from the disruption of intercepted comets. The study
suggests that the LSST has the capability to find black holes by
observing for accretion flares resulting from the impact of small Oort
cloud objects.
"In the vicinity of a black hole, small bodies that approach it will
melt as a result of heating from the background accretion of gas from
the interstellar medium onto the black hole," said Siraj. "Once they
melt, the small bodies are subject to tidal disruption by the black
hole, followed by accretion from the tidally disrupted body onto the
black hole." Loeb added, "Because black holes are intrinsically dark,
the radiation that matter emits on its way to the mouth of the black
hole is our only way to illuminate this dark environment."
Future searches for primordial black holes could be informed by the
new calculation. "This method can detect or rule out trapped planet-mass
black holes out to the edge of the Oort cloud, or about a hundred
thousand astronomical units," said Siraj. "It could be capable of
placing new limits on the fraction of dark matter contained in
primordial black holes."
The upcoming LSST is expected to have the sensitivity required to
detect accretion flares, while current technology isn’t able to do so
without guidance. "LSST has a wide field of view, covering the entire
sky again and again, and searching for transient flares," said Loeb.
"Other telescopes are good at pointing at a known target but we do not
know exactly where to look for Planet Nine. We only know the broad
region in which it may reside." Siraj added, “LSST's ability to survey
the sky twice per week is extremely valuable. In addition, its
unprecedented depth will allow for the detection of flares resulting
from relatively small impactors, which are more frequent than large
ones."
The new paper focuses on the famed Planet Nine as a prime first
candidate for detection. The subject of much speculation, most theories
suggest that Planet Nine is a previously undetected planet, but it may
also flag the existence of a planet-mass black hole.
"Planet Nine is a compelling explanation for the observed clustering
of some objects beyond the orbit of Neptune. If the existence of Planet
Nine is confirmed through a direct electromagnetic search, it will be
the first detection of a new planet in the solar system in two
centuries, not counting Pluto, said Siraj, adding that a failure to
detect light from Planet Nine—or other recent models, such as the
suggestion to send probes to measure gravitational influence—would make
the black hole model intriguing. "There has been a great deal of
speculation concerning alternative explanations for the anomalous orbits
observed in the outer solar system. One of the ideas put forth was the
possibility that Planet Nine could be a grapefruit-sized black hole with
a mass of five to ten times that of the Earth."
The focus on Planet Nine is based both in the unprecedented
scientific significance that a hypothetical discovery of a planet-mass
black hole in the solar system would hold as well as the continued
interest in understanding what’s out there. "The outskirts of the solar
system is our backyard. Finding Planet Nine is like discovering a cousin
living in the shed behind your home which you never knew about," said
Loeb. "It immediately raises questions: why is it there? How did it
obtain its properties? Did it shape the solar system history? Are there
more like it?"
The research was funded in part by a grant from the Breakthrough
Prize Foundation, and by Harvard’s Black Hole Initiative (BHI), which is
funded by grants from the John Templeton Foundation (JTF) and the
Gordon and Betty Moore Foundation (GBMF).
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