From EarthSky: “How the world came to understand black holes” We cannot get enough of these stories.


From EarthSky

October 25, 2020
Sayali Avachat

Roger Penrose, Reinhard Genzel and Andrea Ghez. They are joint winners of 2020’s Nobel Prize in physics for their work on black holes. Credit: Nobel Media.

Earlier this month (October 6, 2020), the Nobel Prize in physics was announced for two groundbreaking discoveries in astrophysics, both centered on black holes. Half of 2020’s prize went to mathematician Roger Penrose of the University of Oxford (UK) “for the discovery that black hole formation is a robust prediction of the general theory of relativity.” The other half went jointly to Reinhard Genzel of the MPG Institut für extraterrestrische Physik(DE) in Germany and Andrea Ghez of University of California, Los Angeles, “for the discovery of a supermassive compact object at the center of our galaxy.”

It was a great moment for black hole physics as well as for the astronomy and astrophysics field in general. And it’s a wonderful time to contemplate the fascinating history of black hole science.

What are black holes?

Black holes are exotic objects in space. The classic scenario for black hole formation centers on a massive star that runs out of the internal fuel it needs to shine. The star collapses under the pull of its own self-gravity, leaving behind a high-density, compact object with an immense gravitational pull. A black hole is a place in space containing an object so dense and so compact that it forms a region around itself from which light cannot escape. The boundary of this region is known as an event horizon. Once past a black hole’s event horizon, the gravitational pull of the hole is inexorable.

If there is material in space near the black hole – and if this material draws too close – it’s pulled inside. But it doesn’t just drop all at once into the hole; instead, it forms a glowing disk surrounding the black hole called an accretion disk. Friction within the accretion disk can heat the disk to billions of degrees, causing it to emit radiation across the electromagnetic spectrum. Thus, although no light can escape a black hole, astronomers can observe black holes in space via their accretion disks.

What’s more, in the process of conservation of angular momentum, black holes can cause outbursts which come out perpendicular to the accretion disk. These outbursts are called jets by astronomers, and they can propel material out into space at relativistic speeds, that is, speeds that are a significant fraction of the speed of light (186,000 miles or 300,000 km per second). Astronomers can study black hole jets, too, to learn more about black holes.

Development of theories of black holes

All of the above was theory, developed in the 20th century. Albert Einstein’s General Theory of Relativity, published in 1916, contained the seeds of the modern concept of black holes, although the first ever mention of a similar concept is found in 1783, when an English natural philosopher by the name of John Michell theorized the existence of massive objects from which light cannot escape.

Einstein’s theory of relativity discusses the curvature of space-time as a result of gravity. This curvature causes an object to move along a curved path equivalent to a straight line in the absence of gravity. The theory allowed for the existence of matter packed in small and infinitely warped space. The theory was published as The Field Equations of Gravitation in 1915.

While serving in the German Army during World War I, astronomer and director of the Astrophysical Observatory in Potsdam Karl Schwarzschild was the first to solve Einstein’s field equations. His solution successfully described how space-time is curved, not just around a planet or a star, but also around theoretical high-density masses, such as black holes. In the space around an object that’s dense enough, and massive enough, gravity is so strong that even light – the fastest-moving stuff in the universe at 186,000 miles (300,000 km) per second – cannot escape. Thus it was Schwarzschild who first conceived of the event horizon, or boundary region around a black hole. Today, physicists speak of the Schwarzschild radius, which is (basically) the radius of a black hole’s event horizon. Schwarzschild’s solution to Einstein’s field equations also elegantly explained the concept of a singularity – the central point of a black hole – a point in space where all the laws of physics break down.

At first, this concept was considered a mathematical curiosity. Scientists, including Einstein, had no idea such objects could exist in nature.

But 50 years later, in 1965, Roger Penrose, working with the great theoretical physicist and cosmologist Stephen Hawking, showed that the black holes can indeed exist in nature and that they can form through a stable and robust process. And in fact, for some stars, black holes are the ultimate fate, an unavoidable outcome of stellar collapse.

The momentous work by Penrose and Hawking opened a new era in the study of black holes. Penrose’s work was also pivotal in showing how black holes emit energy through the Penrose process, in the form of jets and outbursts.

In the meantime, it was physicist John Wheeler who, in 1967, popularized the term black hole. Wheeler summarized Einstein’s equations as:

“Space-time tells matter how to move; matter tells space-time how to curve.”

Observations of black holes

Astronomers didn’t discover the first stellar-mass black hole – Cygnus X-1 – until after the middle of the 20th century.

Left: Image of Cygnus X-1 as observed by the Chandra X-ray observatory. Right: By now iconic artist’s concept of black hole accreting matter from its companion star. Image via (left) NASA/ CXC/ SAO; (right) NASA/ CXC/ M.Weiss.

A 1964 rocket flight revealed Cygnus X-1 as one of the strongest sources of X-rays that had yet been seen from Earth. By the 1970s, most astronomers believed Cygnus X-1 was indeed a black hole. It’s now thought to be a black hole with a mass some 14.8 times that of our sun and an event horizon with a radius of around 27 miles (44 km). That’s in contrast to our sun’s radius of about 433,000 miles (696,000 km).

Stellar-mass black holes are hard to find because of their quiescent nature. They might display short and unpredictable outbursts when some passing material strikes their accretion disks, after which they might go quiet for decades.

That is why it took the discovery of supermassive black holes at the centers of most galaxies, including our own Milky Way, to give black hole science its real boost.

Supermassive black holes

Today, astronomers believe that most galaxies harbor supermassive black holes in their centers. Supermassive black holes have masses equivalent to millions to billions of solar masses and are believed to form in the centers of galaxies around the same time as the galaxy is forming. Over 100,000 supermassive black hole candidates have been observed to date, many more than the number of known stellar-mass black holes.

Among the many observed black hole candidates, the one at the center of our own Milky Way galaxy is called Sagittarius A* (Sgr A*, pronounced Sagittarius A-star). Two independent studies carried out in the last 25 years, led by Andrea Ghez and Reinhard Genzel – joint winners of half of 2020’s Nobel prize in physics – mapped the stars orbiting an invisible object at the center of our Milky Way. Using the powerful telescopes at Keck Observatory in Hawaii and the Very Large Telescope in Chile, the teams focused on one star known as S0-2. S0-2 orbits closer to our galaxy’s central supermassive black hole than any other observed star.

Keck Observatory, operated by Caltech and the University of California, Maunakea Hawaii USA, altitude 4,207 m (13,802 ft).

ESO VLT at Cerro Paranal in the Atacama Desert, •ANTU (UT1; The Sun ),
•KUEYEN (UT2; The Moon ),
•MELIPAL (UT3; The Southern Cross ), and
•YEPUN (UT4; Venus – as evening star).
elevation 2,635 m (8,645 ft) from above Credit J.L. Dauvergne & G. Hüdepohl atacama photo.

Knowing the orbital period of the star S0-2, its very elongated elliptical orbit and the distance of its closest approach to our galaxy’s central black hole enabled scientists to calculate the mass of Sgr A* as the equivalent of 4 million solar masses. The teams were able to observe two full orbits of the star S0-2 around the central black hole, which further bolstered their claims and also proved, through observations, what Einstein, Schwarzchild, and Penrose had predicted in theory about black holes.

SgrA* NASA/Chandra supermassive black hole at the center of the Milky Way, X-ray image of the center of our galaxy, where the supermassive black hole Sagittarius A* resides. Image via X-ray: NASA/UMass/D.Wang et al., IR: NASA/STScI.

Star S0-2 Andrea Ghez Keck/UCLA Galactic Center Group at SGR A*, the supermassive black hole at the center of the Milky Way.

Further validation of Einstein’s general theory of relativity came when, on April 10, 2019, the Event Horizon Telescope collaboration released the first-ever image of [the event horizon] of a black hole* in the relatively nearby (by cosmic standards) galaxy known as Messier 87, visible in the constellation Virgo.

The gargantuan black hole in Messier 87’s center, Messier 87*, weighs a whopping 6.5 billion solar masses.

Messier 87*, The first image of the event horizon of a black hole. This is the supermassive black hole at the center of the galaxy Messier 87. Image via JPL/ Event Horizon Telescope Collaboration released on 10 April 2019.

The galaxy Messier 87 and its famous jet – an energetic outflow of high energy particles from its center – had been observed for several decades. However, this was the first ever successful attempt at direct imaging of its [event horizon]. The image shows a bright ring formed by the bending of light at the boundary of the black hole’s event horizon, caused by its extreme gravitational pull.

*One cannot speak of the image of the black hole itself, because no light emerges from the black hole. It is, after all, black. All that can be imaged is the event horizon which is the thin area which surrounds the black hole.

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Deborah Byrd created the EarthSky radio series in 1991 and founded EarthSky.orgin 1994. Today, she serves as Editor-in-Chief of this website. She has won a galaxy of awards from the broadcasting and science communities, including having an asteroid named 3505 Byrd in her honor. A science communicator and educator since 1976, Byrd believes in science as a force for good in the world and a vital tool for the 21st century. “Being an EarthSky editor is like hosting a big global party for cool nature-lovers,” she says.