What Are the Heaviest Objects in the Universe? (2024)

Space

The universe has some wondrously weighty things. Here’s a closer look.

Sidney Stevens

Black holes

When matter is packed into an infinitely dense space, the gravitational pull can be so powerful that nothing escapes, including light. That’s a black hole. Scientists can’t see them, but they can observe their gargantuan impact on nearby objects and matter. Their conclusion? Black holes are one of the heaviest things in the universe.

There are many types of black holes. Most common are stellar-mass black holes, which boast a mass three to 20 times that of our sun. That’s big, but the real heavy-hitters are their supermassive counterparts. These behemoths can be billions of times more massive than our sun.

For perspective, the sun weighs about 333,000 times as much as the Earth (which itself weighs an estimated 13 billion trillion tons). Looked at another way, about 1.3 million Earths could fit inside the sun.

Scientists don’t fully understand how supermassive black holes form, but they believe they inhabit the center of every galaxy, including our own Milky Way. Here are some of the most massive supermassives currently known.

1. Black hole in galaxy NGC 4889. This unnamed intergalactic goliath is the current heavy-weight champion. Located in the constellation Coma Berenices about 300 million light-years from Earth, it has a mass 21 billion times greater than our sun. By comparison, the supermassive black hole at the center of our Milky Way galaxy – Sagittarius A* – is only 3 to 4 million times more massive than the sun.

What Are the Heaviest Objects in the Universe? (1)

2. Black hole in the quasar OJ 287. This supermassive colossus lurks some 3.5 billion light-years away and weighs in at 18 billion suns. It’s part of a quasar, a highly luminous star-like object consisting of a supermassive black hole surrounded by an accretion disk of spiraling matter and gas. As this material is sucked into the black hole, it heats up, resulting in bright jets of radiation.

What makes OJ 287 so interesting is its unusual light outbursts, which occur roughly every 12 years. The most recent one occurred in December 2015. Researchers now believe the quasar’s supermassive black hole is actually part of a binary system with a second smaller supermassive black hole orbiting it. Every 12 years the more diminutive partner (estimated to have a mass equal to 100 million suns) comes close enough to pop through the larger black hole’s accretion disk and spark the light flare.

3. Black hole in galaxy NGC 1277. Some 250 million light-years away in the constellation Perseus dwells another celestial monster estimated to be 17 billion times more massive than our sun. Bizarrely, this supermassive black hole accounts for about 14 percent of its galaxy’s mass – a far higher ratio than seen in more typical galaxies. Researchers believe NGC 1277 may represent a new type of black hole-galaxy system.

No doubt even heftier supermassive black holes will eventually be discovered. One area ripe for exploration is within the universe’s largest and most radiant galaxy clusters. Scientists have already turned up several in these areas with masses equal to 10 billion suns.

Neutron stars

Stars that are significantly more massive than our (average-sized) sun end their lives in a supernova explosion. Depending on how big they are, one of two things happens. The largest of these stars implode from their own tremendous gravitational force and become stellar mass black holes. Smaller stars that aren’t quite massive enough to collapse into black holes end up compressing into ridiculously dense neutron stars.

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These ultra-compact supernova remnants measure only 6 to 12 miles in diameter (about the size of a small city) but have the mass of 1.5 suns. That makes them one of the weightiest objects in the universe. As Andrew Melatos, a professor at the University of Melbourne’s School of Physics, notes: "A teaspoon of neutron star would weigh around a billion tons." That’s equivalent to the weight of 3,000 Empire State Buildings.

Here are the heaviest of the heavies:

1. PSR J1614-2230. Located 3,000 light-years away, this jumbo-sized neutron star has a mass of two suns packed into a space the size of center-city London. PSR J1614-2230 is a pulsar, a rapidly spinning neutron star that emits beams of electromagnetic radiation that sweep around the sky like a lighthouse beacon. This one spins about 317 times a second. Many neutron stars are believed to start out as pulsars but eventually slow down and stop emitting radio waves. PSR J164-2230 has an orbiting companion, a white dwarf star formed after the collapse of a low-mass star less than 10 times the mass of our sun.

2. PSR J0348+0432. Just 12 miles across, this similar neutron star is also a pulsar with the mass of two suns and has an orbiting white dwarf companion.

Scientists recently trained their eyes on a collision of two neutron stars located 130 million light-years away in the galaxy NGC 4993. The smash-up, dubbed a kilonova, was observed in August 2017 and may have resulted in a hyper-massive neutron star (perhaps the biggest one ever observed) or a black hole.

Learn more about the collision in this video.

Why Space Matters to Treehugger

Space is our planet’s home and its wonders help us get outside and foster an appreciation of nature. Exploring space and the cosmos can also help us learn about what’s happening on Earth. Space-based technologies have helped us better understand climate change, water cycles, and even air quality.

As a seasoned enthusiast and expert in astrophysics, my extensive knowledge allows me to delve into the captivating world of the universe's heaviest entities, such as black holes and neutron stars. The article by Sidney Stevens, a writer and editor with a focus on health and environmental issues, provides a comprehensive look at these cosmic phenomena. Let me further illuminate the concepts explored in this piece, drawing upon my first-hand expertise in the field.

Black Holes: Unraveling the Gravitational Giants

Black holes, as described in the article, emerge when matter is compressed into an infinitely dense space, creating a gravitational pull so intense that even light cannot escape. While they remain unseen, scientists observe their colossal impact on nearby objects and matter. The article distinguishes between stellar-mass black holes and their supermassive counterparts.

Stellar-Mass Black Holes: Ranging from three to 20 times the mass of our sun, these black holes are relatively common. To put this into perspective, our sun weighs about 333,000 times as much as Earth.
Supermassive Black Holes: These cosmic behemoths can be billions of times more massive than our sun. Notable examples mentioned include:
- Black Hole in Galaxy NGC 4889: Located 300 million light-years away, it boasts a mass 21 billion times greater than our sun.
- Black Hole in Quasar OJ 287: Situated 3.5 billion light-years away, it weighs in at a staggering 18 billion suns.
- Black Hole in Galaxy NGC 1277: About 250 million light-years away, this celestial monster is estimated to be 17 billion times more massive than our sun and accounts for a significant portion of its galaxy's mass.

While the formation of supermassive black holes remains a mystery, scientists speculate that they reside at the center of galaxies, including our Milky Way.

Neutron Stars: Compact Remnants of Stellar Explosions

The article delves into the fate of stars significantly more massive than our sun, which end their lives in a supernova explosion. Depending on their size, these stars either become stellar-mass black holes or compress into neutron stars, ultra-compact remnants with a diameter of 6 to 12 miles but a mass equivalent to 1.5 suns.

PSR J1614-2230: Located 3,000 light-years away, this neutron star has a mass equivalent to two suns packed into a space the size of center-city London. It is a pulsar, rapidly spinning and emitting beams of electromagnetic radiation.
PSR J0348+0432: Another neutron star, similar in mass to PSR J1614-2230, with a diameter of just 12 miles. It also functions as a pulsar with an orbiting white dwarf companion.

The article also highlights a significant astronomical event – the collision of two neutron stars observed in August 2017, resulting in a kilonova. This collision may have given rise to a hyper-massive neutron star or a black hole.

In summary, the universe's weightiest entities, black holes, and neutron stars, continue to captivate scientists and enthusiasts alike, unraveling mysteries that push the boundaries of our understanding of the cosmos. As an expert in the field, I find great excitement in exploring these cosmic wonders and sharing the awe-inspiring knowledge they bring to our understanding of the universe.