\n<\/p>\n
In 1974, science fiction author Larry Niven wrote a murder mystery with an interesting premise: could you kill a man with a tiny black hole? I won\u2019t spoil the story, though I\u2019m willing to bet most people would argue the answer is clearly yes. Intense gravity, tidal forces, and the event horizon would surely lead to a messy end. But it turns out the scientific answer is a bit more interesting.<\/p>\n
<\/p>\n On the one hand, it\u2019s clear that a large enough black hole could kill you. On the other hand, a black hole with the mass of a single hydrogen atom is clearly too small to be noticed. The real question is the critical mass. At what minimum size would a black hole become deadly? That\u2019s the focus of a new paper on the arXiv<\/em>.<\/p>\n The study begins with primordial black holes. These are theoretical bodies that may have formed in the earliest moments of the Universe and would be much smaller than stellar-mass black holes. Anywhere from atom-massed to a mass several times that of Earth. Although astronomers have never found any primordial black holes, observations do rule out several mass ranges. For example, any primordial black hole smaller than 1012<\/sup> kg would have already evaporated thanks to Hawking radiation. Anything larger than 1020<\/sup> kg would gravitationally lens stars in the Milky Way. Since we haven\u2019t detected these lensing effects, they must at the very least be exceedingly rare. If they exist at all.<\/p>\n Some theoretical models argue that primordial black holes could be the source of dark matter. If that\u2019s the case, observational limits constrain their masses to the 1013<\/sup> \u2013 1019<\/sup> kg range, which is similar to the mass range for asteroids. Therefore, the study focuses on this range and looks at two effects: tidal forces and shock waves.<\/p>\n Tidal forces occur because the closer you get to a mass, the stronger its gravity. This means a black hole exerts a force differential on you as it gets near. So the question is whether this force differential is strong enough to tear flesh. Asteroid-mass black holes are less than a micrometer across, so even the tidal forces would cover a tiny area. If one passed through your midsection or one of your limbs, there might be some local damage, but nothing fatal. It would be similar to a needle passing through you.<\/p>\n But if the black hole passed through your head, that would be a different story. Tidal forces could tear apart brain cells, which would be much more serious. Since brain cells are delicate, even a force differential of 10 \u2013 100 nanonewtons might kill you. But that would take a black hole at the highest end of our mass range.<\/p>\n Shockwaves would be much more dangerous. In this case, as a black hole entered your body, it would create a density wave that would ripple through you. These shockwaves would physically damage cells and transfer heat energy that would do further damage. To create a shockwave of energy similar to that of a 22-caliber bullet, the black hole would only need a mass of 1.4 x 1014<\/sup> kg, which is well within the range of possible primordial black holes. <\/p>\n So yes, a primordial black hole could<\/em> kill you.<\/p>\n While that makes for a great story, it would never happen in real life. Even if asteroid-mass primordial black holes exist, the number of them out there compared to the vastness of space means that the odds of it happening to anyone in their lifetime are less than one in 10 trillion.<\/p>\n Reference:<\/strong> Niven, Larry. \u201cThe Hole Man.\u201d Analog Science Fiction\/Science Fact<\/em> (1974): 93-104.<\/p>\n Reference:<\/strong> Robert J. Scherrer. \u201cGravitational Effects of a Small Primordial Black Hole Passing Through the Human Body.\u201d arXiv preprint<\/em> arXiv:2502.09734
(2025)<\/p>\nLike this:<\/h3>\n