Destroying the Earth is not so easy. The earth was created to exist. This is a 5,973,600,000,000,000,000,000 ton iron ball, 4,550,000,000 years old. Over the course of its life, the Earth has received more destructive asteroid impacts than you've had for lunch, and continues to merrily run around in orbit. Therefore, dear destroyers of the Earth, this is not an easy task at all. The methods described here are not aimed at the destruction of humanity or life in general, but rather the complete destruction of the planet itself. Moreover, all these methods correspond modern scientific understanding and therefore must work.
1. Annihilated by an appropriate amount of antimatter.
Required: An Earth-sized planet made of antimatter. Currently, antimatter can be produced in very small quantities in huge particle accelerators. It will take forever to create enough antimatter using accelerators, so maybe you can improve this process or come up with a completely new one.
Method: Once you have managed to obtain enough antimatter, simply launch this mass towards the Earth. The subsequent release of energy (according to Einstein's famous formula E=mc2) will be equivalent to the amount that the Sun emits in 89 million years.
What's left: When they collide, matter and antimatter completely annihilate each other. All that will remain of the Earth is a flash of light, expanding in space. This is the most radical method proposed, since the very matter from which the Earth was made ceases to exist. The earth will be impossible to reassemble.
Feasibility assessment: 2/10. It is technically POSSIBLE to create antimatter, so it is technically POSSIBLE to destroy the Earth. But if new methods for creating antimatter are not invented, then it will take an unrealistically huge amount of time to implement it.
A comment: With significantly less antimatter, you could simply blow up the Earth.
2. Split into elementary particles.
Required: Universal fission machine (i.e. particle accelerator), unimaginable amount of energy.
Method: Take every single atom of planet Earth and split it into hydrogen and helium. Splitting heavy elements into hydrogen and helium is the opposite of the self-sustaining reaction in the Sun: you need to put in energy, which is why the energy requirements are so huge.
What's left: While the gas giants Jupiter, Saturn, Uranus and Neptune, composed primarily of helium and hydrogen, are massive enough to hold onto their atmospheres, Earth is not massive enough. In place of the Earth there will be a thin cloud of gas.
Feasibility assessment: 2/10. Technically possible, but again staggeringly inefficient and time consuming. You guys will at least need a few billion years.
3. Sucked in by a microscopic black hole.
Required: Microscopic black hole. Note. Black holes do not last forever; they evaporate due to Hawking radiation. For an ordinary hole, this process will take an unimaginable amount of time, but very small ones can evaporate almost instantly, since the evaporation time depends on the mass. So you would need a black hole with a certain threshold mass, roughly equal to the mass of Mount Everest.
Method: Just place your black hole on the surface of the Earth and wait. Black holes are so dense that they pass through ordinary matter like a rock through air. The black hole will gradually stop in the core of the Earth, and you will only have to wait until it absorbs all the matter of the planet.
What's left: A singularity with an approximate radius of 9 millimeters, which will continue to run merrily in orbit around the Sun.
Feasibility assessment: 3/10. Unlikely, but not impossible.
4. Cooked in a solar firebox.
Required: a means to focus a significant portion of the sun's energy output directly onto the Earth. What are we talking about here? About mirrors, many mirrors. Intercept a few large asteroids for raw materials, and start producing kilometer-long sheets of lightweight reflective materials (aluminized mylar, aluminum foil, nickel foil, or whatever else you can make). The Lits will need to be able to independently change the focal length, since the position of the Sun and Earth will constantly change, so attach several shunting engines, as well as communication and navigation systems, to each leaf. According to preliminary calculations, you will need approximately 2 trillion square kilometers of mirrors.
Method: Control the mirrors in such a way as to focus as much solar energy as possible on the Earth - either at the core or at some point on the surface. Theoretically, the Earth's temperature will rise until the planet completely boils away and turns into a gas cloud.
What's left: Gas cloud.
Feasibility assessment: 3/10. The main problem is what to do to prevent matter from cooling down and the Earth becoming a planet again? In fact, if the planet's surface layers become gaseous, what will cause them to escape into space rather than remain near the surface, absorbing even more energy and preventing the lower layers from heating up? If the amount of energy is not really huge, then at best you will get a gas planet, and then only temporarily.
5. Overpromoted.
Required: Means for accelerating the rotation of the Earth. The acceleration of the Earth's rotation is different from its displacement. An external influence can move the Earth, but will not have any noticeable effect on its rotation. You will need to build rockets or electromagnetic guns at the equator, all facing west. Or something even more exotic.
Method: The theory is that if you spin the Earth fast enough, it will fall apart as the equator moves fast enough to overcome gravity. One revolution in 84 minutes will be enough. Even a slower rotation on its axis will be sufficient, as the Earth will become flatter and more prone to decay as the rotation speed increases.
Feasibility assessment: 4/10. This can be done because Earth-sized bodies have a limit to how fast they can spin before they start to fall apart. However, spinning a planet is much more difficult than moving it. You can't get by with rockets alone.
6. Exploded.
Required: 25,000,000,000,000 tons of antimatter.
Method: This method involves detonating a bomb powerful enough to split the Earth into pieces. In general, the bomb must be large enough. All of mankind's explosives, nuclear and non-nuclear, brought together and detonated at the same time, would create a significant crater and destroy the ecosystem, but would barely scratch the surface of the planet. Evidence indicates that the Earth has been bombed by asteroids in the past with explosions equivalent to the 5 billion atomic bombs that fell on Hiroshima, but traces of such explosions are difficult to find. There's also a problem with gravity. If the explosion is not powerful enough, the pieces will come together again under the influence of mutual gravitational attraction, and the Earth, like a liquid terminator, will be recreated from the fragments.
What's left: The second asteroid ring around the Sun.
Feasibility assessment: 4/10. Well, a little more possible.
7. Sucked in by a giant black hole.
Required: Black hole, powerful rocket engines. The nearest black hole from Earth is 1600 light years away in the direction of the constellation Sagittarius.
Method: Once you have determined the location of your black hole, you need to bring the black hole and the Earth closer together. This is perhaps the most time-consuming part of the plan. For best results, you should move both the Earth and the black hole.
What's left: The earth will become part of the black hole's mass.
Feasibility assessment: 6/10. Very difficult, but definitely possible.
8. Carefully and systematically disassembled.
Required: Mass accelerator. A mass accelerator is a huge electromagnetic gun that was once proposed to carry minerals from the Moon to Earth - you simply load them into the accelerator and fire them in roughly the right direction. Your design must be powerful enough to achieve an escape velocity of 11 kilometers per second. At the rate of a million tons of mass being ejected from the Earth's gravity well per second, this process would take 189,000,000 years. One mass accelerator will be enough, but ideally, it is better to use a lot of accelerators. Alternatively, space elevators or conventional rockets can be used.
Method: Essentially, we will dig up huge chunks of the Earth and launch them into space. All 1021 tons of Earth's mass. Let's ignore atmospheric conditions. Compared to the additional energy expended in overcoming air friction, it would be a rather trivial step to completely burn up the atmosphere before starting the process. Even with the atmosphere destroyed, this method would require a titanic amount of energy.
What's left: Many small pieces, some of which will fall on the Sun, some will be scattered throughout the Solar System.
Feasibility assessment: 6/10. If we wanted to start this process, we can start RIGHT NOW. In fact, given all the debris we have left in orbit, on the Moon, and which is now heading into deep space, this process has already begun.
9. Turned to dust when hit with a blunt instrument
Required: A large, heavy rock about the size of Mars.
Method: Basically, everything can be destroyed if you hit it hard enough. ALL. Find a sufficiently massive asteroid or planet, accelerate the object to impressive speeds, and smack it into the Earth, preferably head-on. The result: a spectacular collision in which the Earth (and, most likely, our cue ball) will turn to dust - scattered into many small pieces, which, if the force of the collision was sufficient, would have enough energy to overcome their mutual attraction and scatter throughout the entire system. Objects smaller than Mars can be used. Let's say a 5,000,000,000,000-ton asteroid accelerated to 90% of the speed of light will do.
What's left: A pile of debris, some the size of the moon, scattered across the solar system.
Feasibility assessment: 7/10. Quite plausible.
Because of scientists, the planet could be destroyed by underground lava, burned by its own atmosphere, or swallowed up by a black hole. Introducing 5 experiments that could destroy the Earth. Considering how many risky self-experiments our long-suffering planet had to endure, it is surprising that it is still alive.
Kola superdeep well
The Kola superdeep well is located in the Arctic Circle at the most northwestern point of Russia and is the deepest underground passage dug into the thickness of the Earth.
Soviet scientists initiated the drilling of the well back in 1970 and by 1989 they reached a level of 12,262 meters.
They wanted to completely drill through the earth's crust and reach the upper layer of the mantle, but they had no idea what this could entail. However, fears about the formation of large-scale earthquakes or the appearance of demons from the Underworld turned out to be unfounded. And work on the project was curtailed due to the fact that at the extreme point of the passage the temperature reached 177 degrees Celsius, which is why molten rock flowed back into the well, preventing scientists from increasing the drilling depth.
Tsar bomb
AN602 (aka “Tsar Bomba”, aka “Kuzka’s Mother”) is a thermonuclear aerial bomb developed in the USSR in 1954-1961. a group of nuclear physicists under the leadership of Academician of the USSR Academy of Sciences I.V. Kurchatov. The most powerful explosive device in the history of mankind. According to various sources, it had from 57 to 58.6 megatons of TNT equivalent. The mass defect during the explosion reached 2.65 kg. The total explosion energy is estimated at 2.4 1017 J.
AN602 had a three-stage design: the nuclear charge of the first stage (calculated contribution to the explosion power - 1.5 megatons) launched a thermonuclear reaction in the second stage (contribution to the explosion power - 50 megatons), and it, in turn, initiated the nuclear “Jekyll reaction” Haida" (nuclear fission in uranium-238 blocks under the influence of fast neutrons generated as a result of the thermonuclear fusion reaction) in the third stage (another 50 megatons of power), so that the total calculated power of AN602 was 101.5 megatons.
This bomb option was rejected due to the extremely high level of radioactive contamination, as well as assumptions that the detonation of a charge of such gigantic power could lead to the initiation of a self-sustaining chemical reaction involving nitrogen, which could theoretically lead to an uncontrolled ignition of the entire atmosphere of the Earth. These hypotheses led to a reduction in the estimated yield of the explosion by almost half, to 51.5 megatons.
The Large Hadron Collider
When scientists officially announced the creation of the Large Hadron Collider project on September 10, 2008, some began to believe that this device would lead to the destruction of the entire world.
The $6 billion particle accelerator project was created to accelerate beams of protons through a 27-kilometre tunnel loop and then collide, creating microscopic black holes believed to have appeared in the immediate aftermath of the Big Bang.
Some believed that the resulting black holes would grow uncontrollably until they engulfed the Earth. However, scientists reject these rumors, since it has already been calculated that every black hole has a limit, after which it evaporates. This phenomenon is known as Hawking radiation.
"Starfish Prime"
The Earth's magnetosphere is an important protective layer containing charged particles that protect the Earth's atmosphere from the harmful effects of the solar wind. What would happen if a large nuclear bomb exploded in this magnetosphere?
The United States decided to find out in 1962. Well, among other things, the purpose of the experiment was to find a possible way to intercept Soviet nuclear missile charges while still in space orbit.
A nuclear warhead with a 1.45-megaton W49 charge launched from a Thor rocket was detonated at an altitude of 400 kilometers above Johnston Atoll in the Pacific Ocean.
The almost complete absence of air at an altitude of 400 km prevented the formation of the usual nuclear mushroom. However, other interesting effects were observed during a high-altitude nuclear explosion. In Hawaii, at a distance of 1,500 kilometers from the epicenter of the explosion, under the influence of an electromagnetic pulse, three hundred street lights (not all, street lighting is visible in the photo), televisions, radios and other electronics were damaged. A glow could be seen in the sky in this region for more than seven minutes. It was observed and filmed from the Samoan Islands, located 3,200 kilometers from the epicenter.
Project SETI
This project to search for contacts with “extraterrestrial intelligence” (“Search for Extraterrestrial Intelligence”) includes a set of activities to detect and attempt to communicate with representatives of extraterrestrial civilization.
Back in 1896, Nikola Tesla suggested that radio communications could be used to establish contact with aliens. In 1899, it seemed to him that he even received signals from Mars. In 1924, the United States government declared "National Radio Day" from August 21 to 23, 1924, when scientists could scan the airwaves for radio frequencies from the red planet.
Modern methods of research under the SETI program include the use of ground-based and orbital telescopes, large radio telescopes with distributed data processing. However, some are wary of such attempts by humanity to get closer to representatives of extraterrestrial civilization - after all, this may attract unnecessary attention to our planet. Thus, cosmologist Stephen Hawking recalls that the history of mankind already knows cases and results when a less technically developed civilization collides with a more advanced one.
A lot of information is written and shown that our planet will soon come to an end. But destroying the Earth is not so easy. The planet has already been subjected to asteroid attacks, and will survive a nuclear war. So let's look at some ways to destroy the Earth.
The Earth weighs 5.9736·1024 kg and is already 4.5 billion years old.
1. The earth may simply cease to exist
You don't even need to do anything. Some scientists have suggested that one day all the countless atoms that make up the Earth will suddenly spontaneously and most importantly, simultaneously, cease to exist. In fact, the odds of this happening are about a googolplex to one. And the technology that makes it possible to send so much active matter into oblivion is unlikely to ever be invented.
2. Will be absorbed by strangelets
All you need is a stable strangelet. Take control of the Relativistic Heavy Ion Collider at Brookhaven National Laboratory in New York and use it to create and maintain stable strangelets. Keep them stable until they get out of control and turn the entire planet into a mass of strange quarks. True, keeping strangelets stable is incredibly difficult (if only because no one has yet discovered these particles), but with a creative approach anything is possible.
A number of media outlets talked about this danger some time ago and that this is exactly what is being done now in New York, but in reality the chances that a stable strangelet will ever be formed are almost zero.
But if this happens, then in place of the Earth there will only be a huge ball of “strange” matter.
3. Will be swallowed up by a microscopic black hole
You'll need a microscopic black hole. Please note that black holes are not eternal, they evaporate under the influence of Hawking radiation. For medium-sized black holes, this requires an unimaginable amount of time, but for very small ones this will happen almost instantly: the evaporation time depends on the mass. Therefore, a black hole suitable for destroying a planet should weigh approximately the same as Mount Everest. It is difficult to create one, because a certain amount of neutronium is required, but you can try to make do with a huge number of atomic nuclei compressed together.
Then you need to place a black hole on the surface of the Earth and wait. The density of black holes is so high that they pass through ordinary matter like a rock through air, so our hole will fall through the Earth, making its way through its center to the other side of the planet: the hole will scurry back and forth like a pendulum. Eventually, having absorbed enough matter, it will stop at the center of the Earth and “eat up” the rest.
The likelihood of such a turn of events is very low. But it’s no longer impossible.
And in place of the Earth there will be a tiny object that will begin to revolve around the Sun as if nothing had happened.
4. Explode as a result of the reaction of matter and antimatter
We will need 2,500,000,000,000 antimatter - perhaps the most “explosive” substance in the Universe. It can be produced in small quantities using any large particle accelerator, but it will take a long time to collect the required amount. You can come up with an appropriate mechanism, but it is much easier, of course, to simply “turn over” 2.5 tril. tons of matter through the fourth dimension, turning it into antimatter in one fell swoop. The result will be a huge bomb that will immediately tear the Earth into pieces.
How difficult is it to implement? The gravitational energy of the planetary mass (M) and radius (P) are given by the formula E=(3/5)GM2/R. As a result, the Earth will need approximately 224 * 1010 joules. The sun produces this amount for almost a week.
To release that much energy, all 2.5 trils must be destroyed at once. tons of antimatter - provided that the loss of heat and energy is zero, and this is unlikely to happen, so the amount will have to be increased tenfold. And if you still managed to get so much antimatter, all that remains is to simply launch it towards the Earth. As a result of the release of energy (the familiar law E = mc2), the Earth will shatter into thousands of pieces.
In this place there will be an asteroid belt that will continue to revolve around the Sun.
By the way, if you start producing antimatter right now, then given modern technologies, you can just finish it by the year 2500.
5. Will be destroyed by vacuum energy detonation
Don't be surprised: we will need light bulbs. Modern scientific theories say that what we call a vacuum cannot, in fact, rightfully be called that, because particles and antiparticles are constantly being created and destroyed in colossal quantities in it. This approach also implies that the space contained in any light bulb contains enough vacuum energy to boil any ocean on the planet. Consequently, vacuum energy may be one of the most accessible types of energy. All you have to do is figure out how to extract it from light bulbs and use it in, say, a power plant (which is pretty easy to get into without raising suspicion), trigger the reaction, and let it get out of control. As a result, the released energy will be enough to destroy everything on planet Earth, possibly along with the Sun.
A rapidly expanding cloud of particles of different sizes will appear in place of the Earth.
Of course, there is a possibility of such a turn of events, but it is very small.
6. Sucked into a giant black hole
A black hole, extremely powerful rocket engines, and possibly a large rocky planetary body are needed. The closest black hole to our planet is located 1,600 light years away in the constellation Sagittarius, in orbit V4641.
Everything is simple here - you just need to place the Earth and the black hole closer to each other. There are two ways to do this: either move the Earth in the direction of the hole, or the hole towards the Earth, but it is more effective, of course, to move both at once.
This is very difficult to implement, but definitely possible. In place of the Earth there will be part of the mass of the black hole.
The disadvantage is that it takes a very long time for technology to emerge that allows this to be done. Definitely not earlier than the year 3000, plus travel time - 800 years.
7. Carefully and systematically deconstructed
You will need a powerful electromagnetic catapult (ideally several) and access to approximately 2 * 1032 joules.
Next, you need to take a large piece of the Earth at a time and launch it beyond the Earth's orbit. And so over and over again launch all 6 sextillion tons. An electromagnetic catapult is a kind of huge-sized electromagnetic rail gun proposed several years ago for mining and transporting cargo from the Moon to Earth. The principle is simple - load the material into the catapult and shoot it in the right direction. To destroy the Earth, you need to use a particularly powerful model to give the object a cosmic speed of 11 km/s.
Alternative methods for throwing material into space involve the space shuttle or space elevator. The problem is that they require a titanic amount of energy. It would also be possible to build a Dyson sphere, but technology will probably allow this to be done in about 5,000 years.
In principle, the process of throwing matter out of the planet can begin right now; humanity has already sent a lot of useful and not so useful objects into space, so until a certain moment no one will even notice anything.
Instead of the Earth, in the end there will be many small pieces, some of which will fall on the Sun, and the rest will end up in all corners of the solar system.
Oh yes. The implementation of the project, taking into account the ejection of a billion tons per second from the Earth, will take 189 million years.
8. Will fall to pieces when hit by a blunt object
It would take a colossal heavy stone and something to push it. In principle, Mars is quite suitable.
The point is that there is nothing that cannot be destroyed if you hit it hard enough. Nothing at all. The concept is simple: find a very, very large asteroid or planet, give it mind-blowing speed and smash it into the Earth. The result will be that the Earth, like the object that hit it, will cease to exist - it will simply disintegrate into several large pieces. If the impact was strong and accurate enough, then the energy from it would be enough for new objects to overcome mutual attraction and never gather into a planet again.
The minimum permissible speed for an “impact” object is 11 km/s, so provided that there is no loss of energy, our object should have a mass of approximately 60% of the Earth’s. Mars weighs approximately 11% of the Earth's mass, but Venus, the closest planet to Earth, by the way, already weighs 81% of the Earth's mass. If you accelerate Mars more strongly, then it will also be suitable, but Venus is already an almost ideal candidate for this role. The greater the speed of an object, the less mass it can have. For example, an asteroid weighing 10*104 launched at 90% of the speed of light will be just as effective.
Quite plausible.
Instead of the Earth, there will be pieces of rock approximately the size of the Moon, scattered throughout the solar system.
9. Absorbed by a von Neumann machine
All that is needed is a von Neumann machine - a device that can create a copy of itself from minerals. Build one that will run solely on iron, magnesium, aluminum or silicon - basically, the main elements found in the Earth's mantle or core. The size of the device does not matter - it can reproduce itself at any time. Then you need to lower the machines under the earth's crust and wait until two machines create two more, these create eight more, and so on. As a result, the Earth will be swallowed up by a crowd of von Neumann machines, and they can be sent to the Sun using previously prepared rocket boosters.
This is such a crazy idea that it might even work.
The Earth will turn into a large piece, gradually absorbed by the Sun.
By the way, such a machine could potentially be created in 2050 or even earlier.
10. Thrown into the Sun
Special technologies will be needed to move the Earth. The point is to throw the Earth into the Sun. However, ensuring such a collision is not so easy, even if you do not set yourself the goal of hitting the planet exactly on the “target”. It is enough for the Earth to be close to it, and then tidal forces will tear it apart. The main thing is to prevent the Earth from entering an elliptical orbit.
With our level of technology this is impossible, but someday people will figure out a way. Or an accident could happen: an object would appear out of nowhere and push the Earth in the right direction. And what will remain of our planet is a small ball of evaporating iron, gradually sinking into the Sun.
There is some probability that something similar will happen in 25 years: previously, astronomers have already noticed suitable asteroids in space moving towards Earth. But if we ignore the random factor, then at the current level of technology development, humanity will become capable of this no earlier than the year 2250.
Once upon a time, people did not believe that you could walk on the moon. They once considered it impossible to create a flying car, although today airplanes are the most routine thing. But how soon will humanity be able to destroy the Earth entirely? Destroying such a large space object as a planet is not easy, but there are at least 10 ways to achieve this goal:
1. Simultaneous cessation of the existence of atoms
Materials needed: Something to pass the time.
Method: This is the easiest, although least feasible way. You don’t need to do anything special, just relax and do what you love until all 200,000,000,000,000,000,000,000,000,000,000,000,000 atoms of the Earth cease to exist. And that's it - the Earth is destroyed! But the chances of this are less than getting into Googleplex - Google headquarters.
Probability of Plan Fulfillment: 0/10
As a result, in place of the Earth: Empty space
2. Destruction with straplets
Required materials: One stable strap is enough. True, a strapel is a hypothetical object consisting of strange matter - relatively speaking, free quarks (up, down and strange), not combined into hadrons.
Method: It is possible to obtain a stable strapel only by gaining access to the American Relativistic Heavy Ion Collider. All that remains is to use it to create a strange shot and keep it in a stable state until it destroys the Earth. And that's it, it's all in the bag! Although, if you think about it, the actual probability of creating a stable strap for such a long period is also zero.
Probability of Plan Fulfillment: 1/10
As a result, in place of the Earth: One big question mark.
3. Absorption by a microscopic “black hole”
Required materials: A device capable of creating a very compact, almost microscopic “black hole” the size of Everest.
Method: Place the black hole on the ground and wait. The “black hole” will fall into the center of the planet and then swallow it all, slowly but surely.
Probability of Plan Fulfillment: 2/10
As a result, in the place of the Earth: an extremely microscopic point of almost zero mass, which will continue to revolve around the Sun, as it happens.
4. Annihilation by antimatter
Materials needed: a mere trifle - 2,500,000,000,000,000,000,000 tons of antimatter, the most versatile explosive that has ever existed in the world. The good old way to get rid of the Earth. And quite light, although creating such an amount of antimatter is, of course, not easy, and you will have to work hard to achieve the result.
Method: Deliver the required amount of antimatter from space to Earth and watch as the planet is torn into a thousand small pieces.
As a result, in the place of the Earth: The second asteroid belt in the Solar System, only this time closer to the star.
5. Vacuum explosion energy
Materials needed: a simple light bulb. Yes, tiny light bulbs can destroy the Earth!
Method: Some people may not be aware, but vacuum energy can potentially cause truly catastrophic consequences. In a vacuum, a 60-watt light bulb can boil all the water on Earth. Of course, destroying the planet itself, which is much harder, would require significantly more energy. But nothing is impossible. Build a power plant that can properly harness vacuum energy and perform all the necessary processes - and then let it run out of control. So you can blow up not only the Earth, but also the Sun itself!
Probability of Plan Fulfillment: 5/10
As a result, in place of the Earth: a rapidly expanding cloud consisting of particles of different calibers.
6. Absorption by a giant “black hole”
Materials needed: a large “black hole” (the closest is 1600 light-years away from our planet) and extremely powerful engines that are capable of transporting the Earth to it.
Method: This is one of the easiest ways to destroy a planet, provided that the objects are already nearby. The plan is extremely simple - however, first you need to bring these two objects together. The journey to the nearest black hole will take only 800 years, provided that the black hole and the Earth are moving towards each other. Apply the sixth method only if you were unable to create a microscopic “black hole”, as described in method No. 3.
As a result, in place of the Earth: a giant piece of a “black hole”.
7. Destruction in parts.
Materials needed: One extremely cool excavator or several smaller machines. Just keep in mind that we will need a power of at least 2 × 10 to the 32nd power of kilojoules.
Method: Here is, finally, the opportunity to immediately begin the destruction of the Earth! All that is required is to take a huge excavator, separate large pieces of the planet and throw them into space. It’s a bit complicated, of course, considering that the force of the excavator must be sufficient to give the pieces a speed of 11 kilometers per second, taking into account calm atmospheric conditions. Well, and take into account that the mass of the Earth is billions of tons, which are influenced by gravity, that it will take about 189,000,000 years to dig. Remember that patience is one of the cardinal virtues.
Probability of Plan Fulfillment: 6/10
The result, in place of the Earth: Billions of tiny pieces of matter floating in space.
8. Impulse impact
Required materials: Something large with a huge mass (Mars would be ideal) and a device that can accelerate it.
Method: Almost anything can be destroyed by the force of momentum generated by the impact of speed on mass. That is, all that needs to be done is to take Mars, accelerate it at least 40-50 kilometers per second and throw it into the Earth. Well, or you can accelerate something smaller, a small asteroid; 10,000,000,000,000-ton crumbs will be enough. And throw it at the Earth at a speed equal to 90% of the speed of light. Such an impulse would be enough to disperse the Earth.
Probability of Plan Fulfillment: 7/10
As a result, in place of the Earth: And again, billions of rock fragments will scatter throughout the solar system.
9. Fonneyman's destruction
Materials Required: One von Neumann self-replicating machine. Von Neumann machines are devices that copy themselves, provided they have the necessary raw materials.
Method: Create a machine that is composed primarily of iron, magnesium and silicon, as the most readily available minerals on Earth. Place it on the ground and watch the machine reproduce itself, destroying the planet.
Probability of Plan Fulfillment: 8/10
As a result, in the place of the Earth: a bunch of self-replicating von Neumann machines on an iron core revolving around the Sun.
10. Throw into the Sun
Required materials: a machine that can move the Earth.
Method: Point the Earth towards the Sun, and that's it. Of course, now this is not very realistic, given the current level of development of human technology. But perhaps the day will come when doing such a thing will be a piece of cake. A large asteroid hitting the Earth from the right direction and at the right speed could do the job just as well.
Probability of Plan Fulfillment: 9/10
As a result, in the place of the Earth: a small ball of boiling iron, plunging into the hot depths of the Sun.
Considering how many risky self-experiments our long-suffering planet had to endure, it is surprising that it is still alive.
The Kola superdeep well is located in the Arctic Circle at the most northwestern point of Russia and is the deepest underground passage dug into the thickness of the Earth.
Soviet scientists initiated the drilling of the well back in 1970 and by 1989 they reached a level of 12,262 meters.
They wanted to completely drill through the earth's crust and reach the upper layer of the mantle, but they had no idea what the danger would be. However, fears about the formation of large-scale earthquakes or the appearance of demons from the Underworld turned out to be unfounded.
And work on the project was curtailed due to the fact that at the extreme point of the passage the temperature reached 177 degrees Celsius, which is why molten rock flowed back into the well, preventing scientists from increasing the drilling depth.
Trinity Test
The Trinity test was part of the American “Manhattan Project” program to develop nuclear weapons. This test, which took place on July 16, 1945, was the world's first explosion of an atomic device.
The initial development of the new era weapon was delayed slightly due to the concerns of scientist Edward Teller, who was involved in the project. He assumed that the detonation of a plutonium charge of such power could lead to the initiation of a self-sustaining chemical reaction involving nitrogen, which could theoretically lead to an uncontrolled ignition of the Earth's atmosphere.
However, further calculations showed that the possibility of such a scenario occurring is extremely low, so the work continued. The explosive power generated as a result of the first nuclear test is estimated at 21 kilotons of TNT.
The explosion of this device reminded project leader Robert Oppenheimer of a line from a Hindu sacred manuscript: “Now I am like Death, destroyer of worlds.”
When scientists officially announced the creation of the Large Hadron Collider project on September 10, 2008, some began to believe that this device would lead to the destruction of the entire world.
The $6 billion particle accelerator project was created to accelerate beams of protons through a 27-kilometre tunnel loop and then collide, creating microscopic black holes believed to have appeared in the immediate aftermath of the Big Bang.
Some believed that the resulting black holes would grow uncontrollably until they engulfed the Earth. However, scientists reject these rumors, since it has already been calculated that every black hole has a limit, after which it evaporates. This phenomenon is known as Hawking radiation.
The Earth's magnetosphere is an important protective layer containing charged particles that protect the Earth's atmosphere from the harmful effects of the solar wind. What would happen if a large nuclear bomb exploded in this magnetosphere?
The United States decided to find out in 1962. Well, among other things, the purpose of the experiment was to find a possible way to intercept Soviet nuclear missile charges while still in space orbit.
Therefore, the explosion of a thermonuclear warhead was initiated at an altitude of 400 kilometers above Johnston Atoll in the Pacific Ocean.
The 1.4-megaton explosion was visible from 1,450 kilometers away in the Hawaiian Islands, where the electromagnetic pulse damaged lighting lines and telephone communications.
Also, an artificial radiation belt formed in lower Earth orbit, which lasted for five years and damaged more than a third of all satellites located at that time.
This project of searching for contacts with “extraterrestrial intelligence” (“Search for Extraterrestrial Intelligence”) includes a set of activities to detect and attempt to communicate with representatives of extraterrestrial civilization.
Back in 1896, he suggested that radio communications could be used to establish contact with aliens. In 1899, it seemed to him that he even received signals from Mars. In 1924, the United States government proclaimed “National Radio Day” from August 21 to 23, 1924, when scientists could scan the airwaves for radio frequencies from the red planet.
Modern methods of research under the SETI program include the use of ground-based and orbital telescopes, large radio telescopes with distributed data processing.
However, some are wary of such attempts by humanity to get closer to representatives of extraterrestrial civilization - after all, this may attract unnecessary attention to our planet.…
Thus, cosmologist Stephen Hawking recalls that the history of mankind already knows cases and results when a less technically developed civilization collides with a more advanced one.
