*The Schwarzschild radius of Earth, calculated using its mass, is approximately 0.0089 millimeters. This means that if Earth were compressed to a size smaller than this radius, it would become a black hole.*

## Earth Schwarzschild Radius Calculator

Schwarzschild Radius: — meters

Object | Mass (kg) | Schwarzschild Radius |
---|---|---|

Earth | 5.972 × 10^24 | 0.0089 millimeters |

## FAQs

**What is the Schwarzschild radius of Earth?** The Schwarzschild radius of Earth is approximately 0.0089 millimeters.

**How do you calculate Schwarzschild radius?** The Schwarzschild radius of an object can be calculated using the formula: Rs = 2 * G * M / c^2, where Rs is the Schwarzschild radius, G is the gravitational constant, M is the mass of the object, and c is the speed of light.

**What is Schwarzschild radius of a black hole?** The Schwarzschild radius of a black hole is directly proportional to its mass. For a non-rotating (Schwarzschild) black hole, the Schwarzschild radius is Rs = 2 * G * M / c^2.

**What is the Schwarzschild radius for a 30 solar mass black hole?** For a 30 solar mass black hole, the Schwarzschild radius is approximately 89 kilometers.

**How big would Earth be if it was a black hole?** If Earth were to become a black hole while maintaining its current mass, its Schwarzschild radius would be around 8.9 millimeters, making it incredibly small compared to its current size.

**Does the universe have a Schwarzschild radius?** The observable universe as a whole does not have a Schwarzschild radius because it doesn’t behave like a single massive object. However, you can calculate a “cosmological Schwarzschild radius” based on the average density of the observable universe, but this concept is more abstract and not directly related to individual black holes.

**What is the Schwarzschild radius of a 10 solar mass black hole?** For a 10 solar mass black hole, the Schwarzschild radius is approximately 29.5 kilometers.

**What is the Schwarzschild radius of a 3 solar mass star?** For a 3 solar mass star, the Schwarzschild radius is approximately 8.9 kilometers.

**How big would the Schwarzschild radius be if the Sun were to be squeezed to make it become a black hole?** If the Sun were to become a black hole while maintaining its current mass, its Schwarzschild radius would be approximately 3 kilometers, significantly smaller than its current size.

**Is a black hole smaller than its Schwarzschild radius?** No, a black hole is not smaller than its Schwarzschild radius. In fact, the Schwarzschild radius defines the boundary of a black hole, known as the event horizon.

**What is the Schwarzschild radius of a 5 solar mass black hole?** For a 5 solar mass black hole, the Schwarzschild radius is approximately 14.7 kilometers.

**What is the Schwarzschild radius of TON 618 black hole?** TON 618 is a supermassive black hole with an estimated mass of about 66 billion times that of the Sun. Its Schwarzschild radius would be proportionally larger, approximately 197.4 million kilometers.

**What is the Schwarzschild radius for Jupiter?** For Jupiter, which is much less massive than a star, the Schwarzschild radius is incredibly small, approximately 2.9 millimeters.

**What is the Schwarzschild radius of a 100 solar mass black hole in kilometers?** For a 100 solar mass black hole, the Schwarzschild radius is approximately 295 kilometers.

**What happens if a 1mm black hole appeared on Earth?** If a 1mm black hole were to appear on Earth, it would quickly start to accrete matter and grow, potentially posing a significant gravitational threat. However, it’s important to note that such small black holes are theoretical and have not been observed.

**What can destroy a black hole?** As of current scientific understanding, black holes do not naturally decay or get destroyed by conventional means. They can only lose mass through a process called Hawking radiation over extremely long time scales, but this is a very slow process for stellar-mass black holes.

**How much would you have to shrink Earth to make it a black hole?** To turn Earth into a black hole, you would need to shrink it down to a size smaller than its Schwarzschild radius, which is approximately 8.9 millimeters. This would require removing a vast amount of mass.

**Can black holes create new universes?** There is currently no scientific evidence to support the idea that black holes can create new universes. This concept is more speculative and often appears in theoretical physics discussions.

**Could our entire universe be inside a black hole?** The idea that our universe might be inside a black hole is a speculative hypothesis, but it has not been proven or widely accepted in the scientific community. It remains a topic of debate and exploration in theoretical physics.

**Can a photon orbit a black hole?** Yes, photons (particles of light) can orbit a black hole if they follow a specific trajectory known as the photon sphere. However, they cannot escape from within the event horizon once they cross it.

**What is the Schwarzschild radius of a neutron star?** The Schwarzschild radius of a neutron star depends on its mass, but for typical neutron star masses (around 1.4 times the mass of the Sun), the Schwarzschild radius is approximately 4.2 kilometers.

**What is the difference between a Schwarzschild black hole and a Kerr black hole?** The main difference is that a Schwarzschild black hole is non-rotating and spherically symmetric, while a Kerr black hole is rotating and possesses angular momentum. Kerr black holes have an additional feature called an ergosphere, which is absent in Schwarzschild black holes.

**How big must a neutron star be to become a black hole?** A neutron star must exceed a critical mass known as the Tolman-Oppenheimer-Volkoff (TOV) limit, which is roughly about 2.17 to 2.5 times the mass of the Sun, to collapse into a black hole.

**What is the biggest black hole ever?** The largest known black holes are supermassive black holes found at the centers of galaxies. The largest known supermassive black hole is estimated to be in the quasar TON 618, with a mass of around 66 billion times that of the Sun.

**What is the Schwarzschild radius of a photon?** Photons do not have mass, so the Schwarzschild radius formula (which involves mass) is not applicable to them. Photons travel at the speed of light and are not subject to gravitational capture like massive objects.

**Is singularity a black hole?** No, a singularity is not the same as a black hole. A singularity is a point in space where the density of matter becomes infinitely high, as predicted by some solutions of Einstein’s equations of general relativity. Black holes have singularities at their centers, but they are surrounded by event horizons.

**What would be the Schwarzschild radius in light years if our Milky Way galaxy of 100 billion stars collapsed into a black hole?** Estimating the Schwarzschild radius for the entire Milky Way galaxy is complex due to its non-uniform mass distribution. However, a rough estimate could be in the order of hundreds of thousands of light years.

**Can you compress something into a black hole?** No, you cannot simply compress something into a black hole through physical pressure. The formation of a black hole typically involves the gravitational collapse of a massive object, such as a dying star.

**What would happen if Jupiter was suddenly replaced by a black hole with the same mass as Jupiter?** If Jupiter were replaced by a black hole with the same mass, its gravitational effects on the solar system would be similar to Jupiter’s. The orbits of other planets and objects in the solar system would remain largely unaffected.

**Is there anything greater than a black hole?** In the context of general relativity, black holes represent regions of extreme spacetime curvature with significant gravitational influence. Beyond black holes, there are concepts like singularities, but our understanding of physics breaks down at such extreme conditions.

**What is the smallest possible black hole radius?** The smallest possible black hole radius is determined by its mass. For a non-rotating black hole (Schwarzschild black hole), the radius is zero at the singularity, but the event horizon forms a non-zero radius based on the mass.

**Which is the nearest black hole to Earth?** The nearest known black hole to Earth is the one in the binary star system V616 Monocerotis, also known as A0620-00 or simply A0620. It’s located in the constellation Monoceros and is approximately 3,000 light years away.

**What is a quasar?** A quasar is a type of extremely bright and energetic active galactic nucleus (AGN) found at the centers of galaxies. Quasars are powered by the accretion of mass onto supermassive black holes and emit intense radiation across the electromagnetic spectrum.

**Can a man become a black hole?** No, a human or any ordinary matter cannot naturally become a black hole. The formation of black holes typically requires the collapse of massive stars or other high-density processes.

**Why can’t light escape a black hole?** Light cannot escape a black hole because the gravitational pull of a black hole is so strong that it warps spacetime to such an extent that all paths, including those of light, lead inward toward the singularity. The event horizon marks the boundary beyond which nothing, not even light, can escape.

**How massive must a stellar corpse be to become a black hole?** A stellar corpse, such as a collapsed core of a massive star, must exceed a critical mass called the Chandrasekhar limit (for white dwarfs) or the Tolman-Oppenheimer-Volkoff (TOV) limit (for neutron stars) to become a black hole. This mass is roughly 2.17 to 2.5 times the mass of the Sun.

**What is the Schwarzschild radius of the Messier 87 black hole?** The black hole at the center of Messier 87 (M87), which was imaged by the Event Horizon Telescope, has an estimated mass of about 6.5 billion times that of the Sun. Its Schwarzschild radius is approximately 19.2 million kilometers.

**What is the radius of a 2 solar mass black hole?** For a 2 solar mass black hole, the Schwarzschild radius is approximately 5.9 kilometers.

**What is Earth’s Schwarzschild radius?** Earth’s Schwarzschild radius is approximately 0.0089 millimeters.

**What is the Schwarzschild radius of a 10 solar mass black hole?** For a 10 solar mass black hole, the Schwarzschild radius is approximately 29.5 kilometers.

**How big would a black hole be with the mass of the Earth?** If a black hole had the same mass as Earth, its Schwarzschild radius would be approximately 8.9 millimeters.

**What is the Schwarzschild radius of a stellar mass black hole?** The Schwarzschild radius of a stellar-mass black hole depends on its mass. For reference, a 3 solar mass black hole has a Schwarzschild radius of about 8.9 kilometers.

**Does the universe have a Schwarzschild radius?** The observable universe as a whole does not have a Schwarzschild radius because it doesn’t behave like a single massive object. However, you can calculate a “cosmological Schwarzschild radius” based on the average density of the observable universe, but this concept is more abstract and not directly related to individual black holes.

**What is the Schwarzschild radius of a 3 solar mass star?** For a 3 solar mass star, the Schwarzschild radius is approximately 8.9 kilometers.

**How big would the Schwarzschild radius be if the Sun were to be squeezed to make it become a black hole?** If the Sun were to become a black hole while maintaining its current mass, its Schwarzschild radius would be approximately 3 kilometers, significantly smaller than its current size.

**How long would a micro black hole take to destroy Earth?** A micro black hole, if it could be created, would likely evaporate rapidly through Hawking radiation and would not pose a threat to Earth. The time it takes for a micro black hole to evaporate depends on its mass and is extremely long for very small black holes.

**Could a black hole destroy Earth at any moment?** No, black holes do not randomly appear and destroy planets. They are typically formed through specific astrophysical processes, such as the collapse of massive stars, and are not a threat to Earth under normal circumstances.

**How long would an Earth-sized black hole last?** An Earth-sized black hole, if it were somehow created, would persist for a very long time due to Hawking radiation. The exact time it takes to evaporate depends on its mass, but for a black hole of Earth’s mass, it would take many billions of years.

**What happens if 2 black holes collide?** When two black holes collide, they merge into a single, more massive black hole. This event produces gravitational waves that propagate through spacetime, and it is one of the phenomena detected by gravitational wave observatories like LIGO and Virgo.

**Can a black hole the size of a coin destroy Earth?** No, a black hole the size of a coin would have an extremely small mass and would pose no threat to Earth. It would evaporate very quickly through Hawking radiation.

**How much is 1 hour in a black hole on Earth?** The experience of time near a black hole is affected by its strong gravitational field. Time dilation near a black hole means that 1 hour for an observer near the event horizon might correspond to a significantly longer time outside the black hole. The exact time dilation factor depends on the black hole’s mass and distance from it.

**How many Earths does it take to fill a black hole?** The number of Earths it would take to fill a black hole depends on the mass of the black hole. A black hole with a mass similar to that of the Sun (about 330,000 times the mass of Earth) would require approximately 330,000 Earths to fill it.

**Is there another universe on the other side of a black hole?** The idea that black holes might lead to other universes or parallel realities is a speculative concept in some theories but has not been proven. It remains a topic of debate and exploration in theoretical physics.

**How many dimensions exist?** In the context of theoretical physics, there are various theories that propose more than the familiar three spatial dimensions and one time dimension. String theory, for example, suggests the existence of additional dimensions, potentially totaling 10 or 11 dimensions. However, these extra dimensions are not directly observable in our everyday experience.

**Are we living in a holographic universe?** The concept of a holographic universe is a theoretical idea that suggests the information describing our three-dimensional universe may be encoded on a two-dimensional surface. This idea has been explored in the context of certain theories, but it is still a topic of ongoing research and debate.

**What’s beyond a black hole?** The interior of a black hole is a region where our current understanding of physics breaks down, and it is often described as a singularity. What exists beyond a black hole, if anything, is a subject of speculation and is not well-understood within the framework of current scientific theories.

**Is it possible to orbit a black hole without falling in?** Yes, it is possible to orbit a black hole without falling in, provided that you are outside the event horizon and your velocity is sufficient to maintain a stable orbit. Objects in stable orbits around a black hole can exist at a safe distance.

**What if the Sun orbited a black hole?** If the Sun orbited a black hole instead of the Milky Way’s central supermassive black hole, the solar system’s dynamics would change, but it would still be possible for planets to maintain stable orbits around the Sun, as long as they remained outside the black hole’s event horizon.

**What is the smallest possible black hole radius?** The smallest possible black hole radius is determined by its mass. For a non-rotating black hole (Schwarzschild black hole), the radius is zero at the singularity, but the event horizon forms a non-zero radius based on the mass.

**Which is the nearest black hole to Earth?** The nearest known black hole to Earth is the one in the binary star system V616 Monocerotis, also known as A0620-00 or simply A0620. It’s located in the constellation Monoceros and is approximately 3,000 light years away.

**What is a quasar?** A quasar is a type of extremely bright and energetic active galactic nucleus (AGN) found at the centers of galaxies. Quasars are powered by the accretion of mass onto supermassive black holes and emit intense radiation across the electromagnetic spectrum.

**Can a man become a black hole?** No, a human or any ordinary matter cannot naturally become a black hole. The formation of black holes typically requires the collapse of massive stars or other high-density processes.

**Why can’t light escape a black hole?** Light cannot escape a black hole because the gravitational pull of a black hole is so strong that it warps spacetime to such an extent that all paths, including those of light, lead inward toward the singularity. The event horizon marks the boundary beyond which nothing, not even light, can escape.

**How massive must a stellar corpse be to become a black hole?** A stellar corpse, such as a collapsed core of a massive star, must exceed a critical mass called the Chandrasekhar limit (for white dwarfs) or the Tolman-Oppenheimer-Volkoff (TOV) limit (for neutron stars) to become a black hole. This mass is roughly 2.17 to 2.5 times the mass of the Sun.

**What is the Schwarzschild radius of the Messier 87 black hole?** The black hole at the center of Messier 87 (M87), which was imaged by the Event Horizon Telescope, has an estimated mass of about 6.5 billion times that of the Sun. Its Schwarzschild radius is approximately 19.2 million kilometers.

**What is the radius of a 2 solar mass black hole?** For a 2 solar mass black hole, the Schwarzschild radius is approximately 5.9 kilometers.

**What is Earth’s Schwarzschild radius?** Earth’s Schwarzschild radius is approximately 0.0089 millimeters.

**What is the Schwarzschild radius of a 10 solar mass black hole?** For a 10 solar mass black hole, the Schwarzschild radius is approximately 29.5 kilometers.

**How big would a black hole be with the mass of the Earth?** If a black hole had the same mass as Earth, its Schwarzschild radius would be approximately 8.9 millimeters.

**What is the Schwarzschild radius of a stellar mass black hole?** The Schwarzschild radius of a stellar-mass black hole depends on its mass. For reference, a 3 solar mass black hole has a Schwarzschild radius of about 8.9 kilometers.

**Does the universe have a Schwarzschild radius?** The observable universe as a whole does not have a Schwarzschild radius because it doesn’t behave like a single massive object. However, you can calculate a “cosmological Schwarzschild radius” based on the average density of the observable universe, but this concept is more abstract and not directly related to individual black holes.

**What is the Schwarzschild radius of a 3 solar mass star?** For a 3 solar mass star, the Schwarzschild radius is approximately 8.9 kilometers.

**How big would the Schwarzschild radius be if the Sun were to be squeezed to make it become a black hole?** If the Sun were to become a black hole while maintaining its current mass, its Schwarzschild radius would be approximately 3 kilometers, significantly smaller than its current size.

**How long would a micro black hole take to destroy Earth?** A micro black hole, if it could be created, would likely evaporate rapidly through Hawking radiation and would not pose a threat to Earth. The time it takes for a micro black hole to evaporate depends on its mass and is extremely long for very small black holes.

**Could a black hole destroy Earth at any moment?** No, black holes do not randomly appear and destroy planets. They are typically formed through specific astrophysical processes, such as the collapse of massive stars, and are not a threat to Earth under normal circumstances.

**How long would an Earth-sized black hole last?** An Earth-sized black hole, if it were somehow created, would persist for a very long time due to Hawking radiation. The exact time it takes to evaporate depends on its mass, but for a black hole of Earth’s mass, it would take many billions of years.

**What happens if 2 black holes collide?** When two black holes collide, they merge into a single, more massive black hole. This event produces gravitational waves that propagate through spacetime, and it is one of the phenomena detected by gravitational wave observatories like LIGO and Virgo.

**Can a black hole the size of a coin destroy Earth?** No, a black hole the size of a coin would have an extremely small mass and would pose no threat to Earth. It would evaporate very quickly through Hawking radiation.

**How much is 1 hour in a black hole on Earth?** The experience of time near a black hole is affected by its strong gravitational field. Time dilation near a black hole means that 1 hour for an observer near the event horizon might correspond to a significantly longer time outside the black hole. The exact time dilation factor depends on the black hole’s mass and distance from it.

**How many Earths does it take to fill a black hole?** The number of Earths it would take to fill a black hole depends on the mass of the black hole. A black hole with a mass similar to that of the Sun (about 330,000 times the mass of Earth) would require approximately 330,000 Earths to fill it.

**Is there another universe on the other side of a black hole?** The idea that black holes might lead to other universes or parallel realities is a speculative concept in some theories but has not been proven. It remains a topic of debate and exploration in theoretical physics.

**How many dimensions exist?** In the context of theoretical physics, there are various theories that propose more than the familiar three spatial dimensions and one time dimension. String theory, for example, suggests the existence of additional dimensions, potentially totaling 10 or 11 dimensions. However, these extra dimensions are not directly observable in our everyday experience.

**Are we living in a holographic universe?** The concept of a holographic universe is a theoretical idea that suggests the information describing our three-dimensional universe may be encoded on a two-dimensional surface. This idea has been explored in the context of certain theories, but it is still a topic of ongoing research and debate.

**What’s beyond a black hole?** The interior of a black hole is a region where our current understanding of physics breaks down, and it is often described as a singularity. What exists beyond a black hole, if anything, is a subject of speculation and is not well-understood within the framework of current scientific theories.

**Is it possible to orbit a black hole without falling in?** Yes, it is possible to orbit a black hole without falling in, provided that you are outside the event horizon and your velocity is sufficient to maintain a stable orbit. Objects in stable orbits around a black hole can exist at a safe distance.

**What if the sun orbited a black hole?** If the Sun orbited a black hole instead of the Milky Way’s central supermassive black hole, the solar system’s dynamics would change, but it would still be possible for planets to maintain stable orbits around the Sun, as long as they remained outside the black hole’s event horizon.

**Is black hole smaller than Schwarzschild radius?** No, a black hole is not smaller than its Schwarzschild radius. The Schwarzschild radius defines the boundary of a black hole, known as the event horizon.

**What is the smallest possible black hole radius?** The smallest possible black hole radius is determined by its mass. For a non-rotating black hole (Schwarzschild black hole), the radius is zero at the singularity, but the event horizon forms a non-zero radius based on the mass.

**Which is the nearest black hole to Earth?** The nearest known black hole to Earth is the one in the binary star system V616 Monocerotis, also known as A0620-00 or simply A0620. It’s located in the constellation Monoceros and is approximately 3,000 light years away.

**What is a quasar?** A quasar is a type of extremely bright and energetic active galactic nucleus (AGN) found at the centers of galaxies. Quasars are powered by the accretion of mass onto supermassive black holes and emit intense radiation across the electromagnetic spectrum.

**Can a man become a black hole?** No, a human or any ordinary matter cannot naturally become a black hole. The formation of black holes typically requires the collapse of massive stars or other high-density processes.

**Why can’t light escape a black hole?** Light cannot escape a black hole because the gravitational pull of a black hole is so strong that it warps spacetime to such an extent that all paths, including those of light, lead inward toward the singularity. The event horizon marks the boundary beyond which nothing, not even light, can escape.

**How massive must a stellar corpse be to become a black hole?** A stellar corpse, such as a collapsed core of a massive star, must exceed a critical mass called the Chandrasekhar limit (for white dwarfs) or the Tolman-Oppenheimer-Volkoff (TOV) limit (for neutron stars) to become a black hole. This mass is roughly 2.17 to 2.5 times the mass of the Sun.

**What is the Schwarzschild radius of the Messier 87 black hole?** The black hole at the center of Messier 87 (M87), which was imaged by the Event Horizon Telescope, has an estimated mass of about 6.5 billion times that of the Sun. Its Schwarzschild radius is approximately 19.2 million kilometers.

**What is the radius of a 2 solar mass black hole?** For a 2 solar mass black hole, the Schwarzschild radius is approximately 5.9 kilometers.

**What is Earth’s Schwarzschild radius?** Earth’s Schwarzschild radius is approximately 0.0089 millimeters.

**What is the Schwarzschild radius of a 10 solar mass black hole?** For a 10 solar mass black hole, the Schwarzschild radius is approximately 29.5 kilometers.

**How big would a black hole be with the mass of the Earth?** If a black hole had the same mass as Earth, its Schwarzschild radius would be approximately 8.9 millimeters.

**What is the Schwarzschild radius of a stellar mass black hole?** The Schwarzschild radius of a stellar-mass black hole depends on its mass. For reference, a 3 solar mass black hole has a Schwarzschild radius of about 8.9 kilometers.

**Does the universe have a Schwarzschild radius?** The observable universe as a whole does not have a Schwarzschild radius because it doesn’t behave like a single massive object. However, you can calculate a “cosmological Schwarzschild radius” based on the average density of the observable universe, but this concept is more abstract and not directly related to individual black holes.

**What is the Schwarzschild radius of a 3 solar mass star?** For a 3 solar mass star, the Schwarzschild radius is approximately 8.9 kilometers.

**How long would a micro black hole take to destroy Earth?** A micro black hole, if it could be created, would likely evaporate rapidly through Hawking radiation and would not pose a threat to Earth. The time it takes for a micro black hole to evaporate depends on its mass and is extremely long for very small black holes.

**Could a black hole destroy Earth at any moment?** No, black holes do not randomly appear and destroy planets. They are typically formed through specific astrophysical processes, such as the collapse of massive stars, and are not a threat to Earth under normal circumstances.

**How long would an Earth-sized black hole last?** An Earth-sized black hole, if it were somehow created, would persist for a very long time due to Hawking radiation. The exact time it takes to evaporate depends on its mass, but for a black hole of Earth’s mass, it would take many billions of years.

**What happens if 2 black holes collide?** When two black holes collide, they merge into a single, more massive black hole. This event produces gravitational waves that propagate through spacetime, and it is one of the phenomena detected by gravitational wave observatories like LIGO and Virgo.

**Can a black hole the size of a coin destroy Earth?** No, a black hole the size of a coin would have an extremely small mass and would pose no threat to Earth. It would evaporate very quickly through Hawking radiation.

**How much is 1 hour in a black hole on Earth?** The experience of time near a black hole is affected by its strong gravitational field. Time dilation near a black hole means that 1 hour for an observer near the event horizon might correspond to a significantly longer time outside the black hole. The exact time dilation factor depends on the black hole’s mass and distance from it.

**How many Earths does it take to fill a black hole?** The number of Earths it would take to fill a black hole depends on the mass of the black hole. A black hole with a mass similar to that of the Sun (about 330,000 times the mass of Earth) would require approximately 330,000 Earths to fill it.

**Is there another universe on the other side of a black hole?** The idea that black holes might lead to other universes or parallel realities is a speculative concept in some theories but has not been proven. It remains a topic of debate and exploration in theoretical physics.

**How many dimensions exist?** In the context of theoretical physics, there are various theories that propose more than the familiar three spatial dimensions and one time dimension. String theory, for example, suggests the existence of additional dimensions, potentially totaling 10 or 11 dimensions. However, these extra dimensions are not directly observable in our everyday experience.

**Are we living in a holographic universe?** The concept of a holographic universe is a theoretical idea that suggests the information describing our three-dimensional universe may be encoded on a two-dimensional surface. This idea has been explored in the context of certain theories, but it is still a topic of ongoing research and debate.

**What’s beyond a black hole?** The interior of a black hole is a region where our current understanding of physics breaks down, and it is often described as a singularity. What exists beyond a black hole, if anything, is a subject of speculation and is not well-understood within the framework of current scientific theories.

**Is it possible to orbit a black hole without falling in?** Yes, it is possible to orbit a black hole without falling in, provided that you are outside the event horizon and your velocity is sufficient to maintain a stable orbit. Objects in stable orbits around a black hole can exist at a safe distance.

**What if the sun orbited a black hole?** If the Sun orbited a black hole instead of the Milky Way’s central supermassive black hole, the solar system’s dynamics would change, but it would still be possible for planets to maintain stable orbits around the Sun, as long as they remained outside the black hole’s event horizon.

GEG Calculators is a comprehensive online platform that offers a wide range of calculators to cater to various needs. With over 300 calculators covering finance, health, science, mathematics, and more, GEG Calculators provides users with accurate and convenient tools for everyday calculations. The website’s user-friendly interface ensures easy navigation and accessibility, making it suitable for people from all walks of life. Whether it’s financial planning, health assessments, or educational purposes, GEG Calculators has a calculator to suit every requirement. With its reliable and up-to-date calculations, GEG Calculators has become a go-to resource for individuals, professionals, and students seeking quick and precise results for their calculations.