Primordial black holes are thought to have formed early in the evolution of the universe. None have been discovered yet but if they do exist and they may be plentiful, drifting almost invisibly through the cosmos, then they might account for dark matter. One possible way to search for them is to see the results of their meals and a bizarre new theory suggests low mass black holes could be captured by neutron stars and become trapped inside, devouring them from within. If these strange objects existed then it would make neutron stars less common in locations where black holes would proliferate as observed around Galactic centre.
Black holes are fascinating objects. Some are formed when supermassive stars die, others (which are theoretical only at this stage) may have formed out of regions of higher density when the universe was young. It is possible they may account for a portion of, or maybe even all of the dark matter that makes up about 27% of the mass-energy content of the universe. Their discovery would certainly help to explain some of the mysteries surrounding dark matter but would also help to explain other observations to; microlensing events, correlations in the X-ray and cosmic infrared background fluctuations and mass, spin and coalescence rates for black holes found by LIGO/Virgo.
LIGO ObservatoryIn the paper published by Roberto Caiozzo, Gianfranco Bertone and Florian Kuhnel they explore the abundance of sub-stellar mass primordial black holes. They use modern analysis techniques and explore the possibility that the primordial black holes could be captured by neutron stars and sink to its core. Previous studies into this possibility have been undertaken most notably and most recently by Y. G ?enolini, P. D. Serpico, and P. Tinyakov in their paper “Revisiting primordial black hole capture into neutron stars.
The attention of Caiozzo and team focussed upon the innermost parsec of the Milky Way galaxy, the Galactic centre. They chose this location to study neutron star captured primordial black holes due to the expected high density of dark matter and the predicted population of pulsars. I should add here that most neutron stars are seen as pulsars. Pulsars are just neutron stars that rotate fast and we see them as producing pulses of radiation at short intervals often between milliseconds and seconds. It’s thought they should exist in their thousands however to date, hardly any have been found within the innermost region. It’s not known why there are so few however the team postulate that it may be due to disruption by the black holes.
This image shows a section of the side view of the Milky Way as measured by ESA’s Gaia satellite. The dark band consists of gas and dust, which dims the light from the embedded stars. The Galactic Centre of the Milky Way is indicated on the right of the image, shining brightly below the dark zone. The box to the left of the middle marks the location of the “Maggie” filament. It shows the distribution of atomic hydrogen. The colours indicate different velocities of the gas. Credit: ESA/Gaia/DPAC, CC BY-SA 3.0 IGO & T. Müller/J. Syed/MPIAMillisecond pulsars (those who spin rate is among the highest) would be an excellent choice for study. They are easy to locate and due to spectroscopic observations, they are thought to exist in large populations in the Galactic bulge, likely also close to Galactic centre. Previous predictions suggest there may be 67 long lived neutron star – X-ray binaries in the innermost region of the centre and these have been shown to be the progenitor of millisecond pulsars. It is therefore reasonable to assume a good population in the Galactic centre.
The rate of capture of primordial black holes by neutron stars in the Galactic centre is the goal of the paper with existing calculations being revisited to produce a more realistic forecast. The team goes one step further though and look at the likelihood of the collapse of a neutron star given the disruption of a primordial black hole. The team find however that, having improved all previous models, that the capture of the primordial black holes cannot explain why there are so few missing pulsars / neutron stars around Galactic centre. The disruption of neutron stars and pulsars is simply not likely to occur within their projected lifetime.
Source : Revisiting Primordial Black Hole Capture by Neutron Stars
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While staying at my sister and brother-in-law’s house near Dulles Airport, I encountered a few things of interest. The first is an arrival lunch at Willard’s BBQ near Dulles, and it was crowded, understandable in view of how good the BBQ was, especially for this area. Here’s my lunch of “burnt beef ends” (hard to find, a mixture of crunchy and juicy parts from brisket), along with two “vegetables” (mac and cheese and a fantastic potato salad), BBQ sauce (not needed) cornbread and, of course, sweet iced tea. I’d recommend this place if you are in the area.
And I had a look at the Virginia History textbook that my brother-in-law had when he was about 13. He remembered it as having grossly distorted the horrors of slavery, which it did in a big way.
My sister found a copy of the book online, and I was appalled to see how slavery was described: as a great benefit to slaves, who got vocational education and had kindly masters and good working conditions. It was disgusting. Have a look at how, as kids, we were taught about slavery in Virginia.
The book:
An arriving enslaved person with his family, all decked out in fancy clothes and greeting his new “master” with glee. The family, too, is all happy and spiffy. The reality, of course, was far different, with slave families packed into the holds of the ships, with those who survived sold off soon after being kidnapped from Africa to the U.S., and families often being separated.
Part of the propaganda; read it!
Meanwhile, in Dobrzyn, Hili plays the peacemaker:
Hili: Let’s not quarrel. A: But we do not quarrel. Hili: I know, but calls for unity are in fashion againHili: Nie kłóćmy się.
Establishing communication with an alien intelligence is one of the news items I, and I’m sure many others, long to see. Since we have started the search for advanced civilisations we have tried numerous ways to detect their transmissions but to date, unsuccessfully. A new paper suggests quantum communication may be the ideal method for interstellar communication. It has many benefits but the challenge is that it would require a receiver over 100km across to pick up a signal. Alas they know we don’t have that tech yet!
The search for alien signals has been undertaken under the banner of the search for extraterrestrial intelligence or SETI for short. It began in 1960 when Frank Drake commenced the first search. It was of course not fruitful but since then, large radio telescopes have been used to undertake searches. There have been many projects but of particular interest has been Project Breakthrough. It has used advanced technology and international collaborations but still there has been no success.
Frank Drake writing his famous equation on a white board. Credit: SETI.orgTo be able to effectively search for alien signals its imperative to fully understand the nature of communication. A quest that started back in 1948 with the development of the modern theory of classical communication. In 1959 it was proposed that human technology was available to send or receive interstellar classical communication which simply requires a message, someone to send it and someone to receive it.
Over the years that followed communication theories developed and quantum information theory emerged. It explores how quantum mechanics has an affect on the storage of and transmission of information. At the centre of the theory is the quantum bit or qubit which can exist in a number of states all at once due to the phenomenon of superposition. In classical information theory, bits of information are either 0 or 1 but in quantum theory they can be any infinite number of combinations with certain probabilities until measured. At that point, the wave function collapses to one of the definite states.
Another key element of quantum theory is entanglement where two or more particles are interconnected so that the state of one is related to the state of the other no matter how far apart they are. With qubits linked in this way data processing can be far faster than in classical model and more secure too. The paper authored by Latham Boyle from the University of Edinburgh suggests that it may be possible to send or receive information between the stars using quantum communications. A previous study by Arjun Berera proposed photon qubits could be used to transmit information over interstellar and even possibly intergalactic distances without loss of coherence.
The concept of quantum coherence describes the ability to maintain the specific quantum state but this alone is not enough for communication. The communication channel must also have sufficient capacity. In addition, specific wavelengths must be used (or avoided for example wavelengths less than 26.5 cm to avoid issues with the cosmic microwave background.) To facilitate this, radio telescopes with a diameter of 100 km must be used. Currently we don’t have the capability to build such instruments and this may explain why, in such a large and old universe, we still haven’t detected any aliens yet! We may simply have to wait until we can build such instruments before aliens can communicate with us.
Source : On Interstellar Quantum Communication and the Fermi Paradox
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A seismic shift occurred in astronomy during the Scientific Revolution, beginning with 16th-century polymath Copernicus and his proposal that the Earth revolved around the Sun. By the 17th century, famed engineer and astronomer Galileo Galilei refined Copernicus’ heliocentric model using observations made with telescopes he built himself. However, it was not until Kepler’s observations that the planets followed elliptical orbits around the Sun (rather than circular orbits) that astronomical models matched observations of the heavens completely.
As it turns out, this very quirk of orbital mechanics may be essential to the emergence of life on planets like Earth. That was the hypothesis put forth in a recent study by a team of astronomers led by the University of Leeds. According to their work, orbital eccentricity (how much a planet’s orbit deviates from a circle) can influence a planet’s climate response, which could have a profound effect on its potential habitability. These findings could be significant for exoplanet researchers as they continue to search for Earth-like planets that could support life.
The team was led by Binghan Liu, a PhD Student in the School of Physics and Astronomy at the University of Leeds, who conducted the research as part of his thesis. He was joined by Daniel R. Marsh, the Priestley Chair in Comparative Planetary Atmospheres (and Liu’s thesis advisor), and other colleagues from Leeds and the Institute of Astronomy at the University of Cambridge. Their paper, “Eccentric orbits may enhance the habitability of Earth-like exoplanets,” was recently published in the Monthly Notices of the Royal Astronomical Society.
The idea of circular orbits has deep roots in Western astronomy, going all the way back to Classical Antiquity. Some examples include Plato and Aristotle, who argued that the then-known celestial bodies (the Moon, Mercury, Venus, the Sun, Mars, Jupiter, and Saturn) were perfect spheres that orbited Earth in concentric circles. This belief endured well into the Scientific Revolution, with both Copernicus and Galileo arguing that the then-known planets (Mercury, Venus, the Earth and the Moon, Mars, Jupiter, and Saturn) orbited the Sun in concentric circles.
It was not until Johannes Kepler introduced the concept of elliptical orbits that scientists could match their astronomical models to the observed motions of the planets. Since then, scientists have learned a great deal about orbital parameters – such as semi-major axis (a), eccentricity (e), axial tilt (?), inclination (i), and periapsis – and how they can influence a planet’s climate over time. These parameters have also become very important for exoplanet studies, as they are vital to determining if a planet could be “potentially habitable.”
For their study, Liu and his colleagues used the Whole Atmosphere Community Climate Model (WACCM6), a high-top interactive Earth-system model capable of simulating conditions on Earth (from the oceans to the upper atmosphere) to simulate Earth-like exoplanets with two different orbital parameters. For one set, they assigned circular orbits (e = 0), while the others were assigned highly eccentric orbits (e = 0.4) – far greater than Earth’s eccentricity (0.016). They were also assigned zero obliquity (? = 0) and a fixed level of annual solar irradiance (aka. annual mean insolation).
After running 30 simulation years for each case, they examined how both groups of exoplanets behaved regarding their climate response. This included latitudinal and seasonal variations in their hydrological cycle (sea ice, land snow, and clouds) and land habitability metrics like surface temperature and precipitation. As they indicated in their paper, exoplanets within the highly eccentric orbit group had 25% more habitable land area for more than 80% of their orbit, with an average increase of 7% for their entire orbital cycle.
Naturally, there were some caveats and addendums that they were sure to include:
“It is important to note that the habitability of land depends on the chosen metric and the duration of time during which the conditions are met for a specific metric. We conclude that, under the same annual mean stellar flux, an Earth-analogue planet with zero-obliquity in a highly eccentric orbit around a Sun-like star may have enhanced land habitability compared to its circular counterpart.”
In other words, the simulations are based on planets with far more eccentric orbits than Earth and are not subject to the same changes in obliquity, which also profoundly impact Earth’s climate (i.e., glacial and inter-glacial periods). Nevertheless, their study demonstrates that planets with eccentric orbits are more likely to be habitable than those with circular orbits that experience little in the way of seasonal variations throughout the year. These results could have significant implications for exoplanet studies and the search for habitable worlds beyond the Solar System.
In addition, they note how astronomers will benefit from next-generation observatories that will be capable of spotting Earth-like exoplanets with eccentric orbits in the near future:
“The detection of highly eccentric terrestrial exoplanets is low due to the limitation of the current observation techniques, which are biased towards close-in and thus, tidally locked exoplanets in circular orbits. However, with the upcoming ground and space telescope missions such as PLATO, ELT, and HWO, more highly eccentric Earth-like rocky exoplanets may be revealed and characterized. Understanding the potential climate outcomes and habitability of highly eccentric rocky exoplanets remains a challenging task.”
Further Reading: MNRAS
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