Comments on: Black Holes . . . https://habitablezone.com/2020/10/22/black-holes/ Mon, 06 Apr 2026 12:03:37 -0700 hourly 1 http://wordpress.org/?v=3.3.1 By: Vitruvius https://habitablezone.com/2020/10/22/black-holes/#comment-45964 Vitruvius Sat, 07 Nov 2020 21:32:05 +0000 https://www.habitablezone.com/?p=84843#comment-45964 Black holes have always fascinated me. Never met any professors on the subject, but there were plenty of books on the matter at the local library. I'm genuinely curious about what "Planck Stars" might be like, and whether we'll see them in science fiction soon enough. Black holes have always fascinated me. Never met any professors on the subject, but there were plenty of books on the matter at the local library.

I’m genuinely curious about what “Planck Stars” might be like, and whether we’ll see them in science fiction soon enough.

]]> By: DanS https://habitablezone.com/2020/10/22/black-holes/#comment-45764 DanS Wed, 28 Oct 2020 15:46:53 +0000 https://www.habitablezone.com/?p=84843#comment-45764 <blockquote><center><a href="https://www.space.com/what-happens-black-hole-center" rel="nofollow"><strong><font color="#66FFCC">What Happens at the Center of a Black Hole?</font></strong></a> <font size="2" color="white">FOLLOWUP</font></center> <font size="1" color="white">By <a href="https://www.space.com/author/paul-sutter" rel="nofollow"><font color="#C9B6B6">Paul M. Sutter</font></a> | <font size="1" color="white">By <a href="http://www.pmsutter.com/#intro" rel="nofollow"><font color="#C9B6B6">Credible</font></a> SPACE.com Contributor</font> <b>OCTOBER 27, 2020 | </b> The singularity at the center of a black hole is the ultimate no man's land: a place where matter is compressed down to an infinitely tiny point, and all conceptions of time and space completely break down. And it doesn't really exist. Something has to replace the singularity, but we're not exactly sure what. Let's explore some possibilities. <center><img src="https://cdn.mos.cms.futurecdn.net/ajp5rxyAPMV7Zdxk4zRfQH-970-80.jpg.webp" height="300"></center> <font size="1" color="white">Artist's concept of the MWC 656 system, which consists of a massive "Be" star and a companion black hole. The star rotates at very high speed, ejecting an equatorial disc of matter that is transferred to the black hole through an accretion disc. (Image: © Gabriel Pérez Díaz, Servicio MultiMedia (IAC))</font> <b>Planck stars</b> It could be that deep inside a black hole, matter doesn't get squished down to an infinitely tiny point. Instead, there could be a smallest possible configuration of matter, the tiniest possible pocket of volume. This is called a Planck star, and it's a theoretical possibility envisioned by loop quantum gravity, which is itself a highly hypothetical proposal for creating a quantum version of gravity. In the world of loop quantum gravity, space and time are quantized — the universe around us is composed of tiny discrete chunks, but at such an incredibly tiny scale that our movements appear smooth and continuous. This theoretical chunkiness of space-time provides two benefits. One, it takes the dream of quantum mechanics to its ultimate conclusion, explaining gravity in a natural way. And two, it makes it impossible for singularities to form inside black holes. As matter squishes down under the immense gravitational weight of a collapsing star, it meets resistance. The discreteness of space-time prevents matter from reaching anything smaller than the Planck length (around 1.68 times 10^-35 meters, so…small). All the material that has ever fallen into the black hole gets compressed into a ball not much bigger than this. Perfectly microscopic, but definitely not infinitely tiny. This resistance to continued compression eventually forces the material to un-collapse (i.e., explode), making black holes only temporary objects. But because of the extreme time dilation effects around black holes, from our perspective in the outside universe it takes billions, even trillions, of years before they go boom. So we're all set for now. <a href="https://www.space.com/what-happens-black-hole-center" rel="nofollow"><font color="#C9B6B6">MORE: <b>Gravastars Let's go for a spin</b></font></a> </blockquote>

What Happens at the Center of a Black Hole?
FOLLOWUP

By Paul M. Sutter | By Credible SPACE.com Contributor

OCTOBER 27, 2020 | The singularity at the center of a black hole is the ultimate no man’s land: a place where matter is compressed down to an infinitely tiny point, and all conceptions of time and space completely break down. And it doesn’t really exist. Something has to replace the singularity, but we’re not exactly sure what.

Let’s explore some possibilities.


Artist’s concept of the MWC 656 system, which consists of a massive “Be” star and a companion black hole. The star rotates at very high speed, ejecting an equatorial disc of matter that is transferred to the black hole through an accretion disc.
(Image: © Gabriel Pérez Díaz, Servicio MultiMedia (IAC))

Planck stars
It could be that deep inside a black hole, matter doesn’t get squished down to an infinitely tiny point. Instead, there could be a smallest possible configuration of matter, the tiniest possible pocket of volume.

This is called a Planck star, and it’s a theoretical possibility envisioned by loop quantum gravity, which is itself a highly hypothetical proposal for creating a quantum version of gravity. In the world of loop quantum gravity, space and time are quantized — the universe around us is composed of tiny discrete chunks, but at such an incredibly tiny scale that our movements appear smooth and continuous.

This theoretical chunkiness of space-time provides two benefits. One, it takes the dream of quantum mechanics to its ultimate conclusion, explaining gravity in a natural way. And two, it makes it impossible for singularities to form inside black holes.

As matter squishes down under the immense gravitational weight of a collapsing star, it meets resistance. The discreteness of space-time prevents matter from reaching anything smaller than the Planck length (around 1.68 times 10^-35 meters, so…small). All the material that has ever fallen into the black hole gets compressed into a ball not much bigger than this. Perfectly microscopic, but definitely not infinitely tiny.

This resistance to continued compression eventually forces the material to un-collapse (i.e., explode), making black holes only temporary objects. But because of the extreme time dilation effects around black holes, from our perspective in the outside universe it takes billions, even trillions, of years before they go boom. So we’re all set for now.

MORE:
Gravastars
Let’s go for a spin

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