A paperclip-sized probe will research the edge of the black hole in the distant future.

  A paperclip-sized probe will research the edge of the black hole in the distant future. 

"Illustration of a gram-scale nanocraft journeying towards a black hole." (Rude Baguette)

Researchers plan to create a paperclip-sized probe whose purpose is to transmit information from the edge of the black hole event horizon. That probe will be sent to the black hole's material disk. And there it can use quantum technology like hovering quantum or nanoparticles to capture and send information from that area. The material disk will pump energy to those particles, and the observer can follow those oscillations from outside the material disk. 

One of the most fascinating versions of the data transmission from that ultimate high-energy area is to use superpositioned and entangled particle pairs. The material disk will pump energy to particle that is in it. And then another particle will receive information that the first particle sends. That probe will act basically without electronics. The system must only put a particle pair. Where another particle is in the lower energy level. To the superposition and entanglement. When the probe closes the black hole, its material disk will raise the particles' energy level in the probe, called Cosimo Bambi can transfer data to the receiver. 

The Cosimo Bambi can make this journey to 20-25 light-years away from Earth. But the problem is this. There are no known black holes in that distance. The mission will be completed in about 70 years. But that requires. There is a black hole in that distance. The closest known black hole is 1560 light-years from Earth. And that means the mission is doomed to fail if there is no black hole closer to Earth. 

The probe could use quantum technology and high-power lasers to travel near black holes. But there is one problem: the distance to the closest known black hole is enormous. There is possiblity that there is a black hole just 20-25. light-years away from the Earth. But there should be a confirmed black hole in that distance that the probe can reach it. 

The problem is always similar. The key problem is how to take this probe close enough to the black hole. The closest known black hole is about 1560 light-years away from Earth. That means the journey to that black hole takes a very long time. But the black hole probe gives interesting ideas for the futuristic quantum computers. 

Maybe this is possible in the future...

This keeps the transmitting side in quantum entanglement on a higher energy level than the receiving particle. These kinds of systems can also be used to create new types of quantum computers. The idea is that the transmitting sides of the quantum entanglements are at extremely high temperatures. And the receiving particle's energy level is as low as possible. If the system can use a black hole for that purpose, the quantum computer can put an artificial, or small primordial black hole, into the ball-sized chamber. Then the data will be driven to transmitter particles that are in the capsules. 

Then the quantum computer will send those capsules to the black hole. And the plasma around it keeps the transmitter-side particles in a higher energy level than the receiving particles. Maybe. This kind of system can operate using the regular, high-energy plasma. The idea is that the data will transfer to the transmitting particles that are in the capsule. The capsule that can be some kind of fullerene will act like a yoyo. 

The system will send it to the plasma. When plasma or some kind of EM field is around the capsule. And its energy level rises all the time. That helps to keep the transmitter side temperature in the quantum entanglement at a higher level. The temperature in the receiving particles can be as low as possible. That maximizes the time that the system can sustain quantum entanglement. 

https://www.rudebaguette.com/en/2025/08/one-gram-probe-to-black-hole-in-70-years-physicist-unveils-laser-driven-mission-to-test-einsteins-theory-in-deep-space/#google_vignette

https://scitechdaily.com/paperclip-sized-probe-could-take-us-to-the-edge-of-a-black-holes-event-horizon/

For the first time probe has touched the Sun.

 For the first time probe has touched the Sun. 

NASA Parker probe has been dive in the Sun. That probe used interesting technology that helped to keep it cool. There could be possible to make the probe dive even deeper by using a magnetic field that pushes the plasma away from the probe. That would decrease the interaction between the probe and the plasma that comes from the Sun. 

The reason why Parker was sent to its mission. Is that it should collect data from the solar wind. The solar wind is high-energetic plasma that can destroy spacecraft. But there is another reason why close contact with the Sun is needed. The mission of probes like Parker is to collect data for the fusion tests. The power source of the Sun is fusion reaction. And the close contact with the Sun is the thing that can help to model the conditions that are making fusion possible. 

In some visions, the probes like Parker can collect antimatter from the solar atmosphere. The probe would travel to the sun.  Then that antimatter collector dives deep into the corona. Then it could open the solar sail and solar wind can push the probe back to Earth. 

Antimatter production is extremely expensive. And the probe could create it by putting the beta particles of the solar wind impact with gold leaf. Antimatter can use in fusion reactors to start the fusion reaction. 

The antimatter is creating an extremely high energy load. And that energy can use for starting and maintaining fusion reactions. The antimatter can make annihilate with material around the plasma-ring at Tokamak-type reactors. And that energy dose can start a fusion reaction. And it can raise the temperature after certain periods. The use of antimatter is to boost the fusion reaction in the fusion reactors. 

When the fusion reactor will start to turn too cold small dose of antimatter can turn the temperature to the needed level. The problem with the fusion rector is that the needed temperature is higher than in the Sun's nucleus. In the fusion reactors, the pressure of the nucleus of the sun must compensate by rising temperature to so high level. That the heat replaces missing pressure.  

The use of antimatter is one of the answers to how to create enough energy for starting self-maintaining fusion. But the high price would limit the use of antimatter for that purpose. So antimatter can collect from space. 

https://scitechdaily.com/parker-solar-probe-for-the-first-time-in-history-a-spacecraft-has-touched-the-sun/

https://en.wikipedia.org/wiki/Tokamak

NASA is launching DART (Double Asteroid Redirection Test) to space

The DART (Double Asteroid Redirection Test) vehicle's computer is equipped with multipurpose artificial intelligence that allows it to navigate to an asteroid. Then that probe shoots the asteroid by using kinetic energy arrows that can turn the asteroid out of its course. The thing in this kind of operation is to keep the asteroid in one piece. The DART is using the impact technique where the satellite is impacting the asteroid. Pushing it away from the trajectory. 

The idea is that DART itself will push the asteroid to another trajectory. But maybe the future versions of that kind of system are the darts. Small sub-probes that are impacting asteroid and then push it. When we are thinking about kinetic energy vehicles. Also, so-called dummy rockets can use for pushing asteroids away from their course. The rockets might equip with an impact cushion or gel head that makes the impact softer. At first, the manipulator's arm will throw the rocket into an asteroid. Then they would touch the surface of the asteroid. And that thing activates the rocket engines. 

There is there might be also the possibility to use soft-head rockets. Those are not penetrating the asteroids. If we think of the possibility that the system is used for asteroid mining. 

The penetration ammunition would be more useful if the purpose of the system is to cut the asteroid in pieces. The idea is that the penetrating ammunition would start to resonate in the asteroid. And that will break the asteroid to pieces. And those pieces can pull near Earth where they can drop to the ground by using return capsules. 

The small-size intelligent rockets can also use in ASAT or killer satellites. The idea of this kind of killer satellite is that it would shoot the lower orbiter satellites with its darts. And then it would push those satellites back to the atmosphere without breaking their core. The internal artificial intelligence makes it possible that the satellite can search the target satellites without communication between it and ground stations. So the satellite can be silent when it approaches its target and shoots the impact vehicle to it. 

When we are thinking about the kinetic energy systems that are just pushing asteroids away from the trajectory those systems might be useful for the killer satellites. If the satellite shoots the target by using the gel or some other impact cushion that keeps the target in one piece. 

But it makes it fall to the ocean. Keeping the target satellites in one piece is a very good idea because that keeps the orbiter clean from the debris. The killer satellites are suitable systems for destroying enemy communication and recon satellites. Also, things like orbiter lasers can turn away from their course by using the pushing impact ammunition. The rocket will simply push the laser weapon to the atmosphere. 

https://scitechdaily.com/planetary-defense-nasa-prepares-to-launch-dart-to-deflect-asteroid-with-kinetic-impact/

Image: https://scitechdaily.com/planetary-defense-nasa-prepares-to-launch-dart-to-deflect-asteroid-with-kinetic-impact/

https://interestandinnovation.blogspot.com/

What kind of lifeforms might be live on Enceladus?

(Picture 1)

https://futurism.com/alien-life-saturn-moon/

There is a moon named Enceladus orbiting a Saturn, what maybe has alien life form. This life form might exist because this moon has liquid water under its icy surface. And the liquid water is possible because the tidal power of Saturn keeps it warm. If we will find the living organisms in that place, that organism might be similar, what is found near “black smokers” at the bottom of the ocean. Those cells animals can synthesize oxygen in their bodies, and they don’t need free oxygen for their living.


But if there would be organisms what uses photosynthesis, their form might be like long seaweeds, what uses erupting icy geysers to raise very high from this moon surface. The eruption of geyser would pull those cell lines upwards, and that would help them to get enough light for photosynthesis. This is only thinking about this alien life form, and we are not sure is there an alien life in that icy moon.


And if there is an extraterrestrial life, we must ask next question about the life of that moon This question is, could that organism be a threat to us? There could be many things, what could influence that thing. One is that organism might be “Gaia”. This means that there are only one species of bacteria or amoeba in this moon. And that kind of organism might be very sensitive because it doesn’t need to fight for live space. So if those icy geysers would drive those cells high enough, would some of them travel near Earth. If those cells would be like covert lifeform, what has silicon cod, that organism might survive alive in empty space. But this is only theory.


There is one very small possibility that those cells could be travel to our home planet. It would be the scenario, that one of those geysers would drop some cells to the orbiter of Saturn, and then there would become the comet, what hits to those cells. When this comet or asteroid comes near Earth, that could deliver those cells to Earth. This scenario would not be probable, and if those cells could be live, that case would need the thing, that the asteroid or comet would turn around, and the shadow of this rock would cover them of the ultraviolet radiation of Sun.


But there is a possibility that there is no life in that life form on that moon. And it will give us an interesting opportunity to use Enceladus as a laboratory or as a "living lab", where the human race can test and analyze the evolution. In this case, to this moon would send the probe, what has tiny bacteria in the capsule. And when those bacteria would release to that moon, would the scientists discover, what evolution will make, if those organisms are in the fully isolated place. This test would mean that Enceladus would be polluted by biological organisms. Enceladus would be suitable for that kind of action because it is so far away from Earth. But this is the only vision, not the real experiment. But it is possible to send the probe to that moon, and deliver the organism to that surface.

Sources:

https://futurism.com/alien-life-saturn-moon/

Picture 1:

https://3c1703fe8d.site.internapcdn.net/newman/gfx/news/hires/2012/excitingnewe.jpg

https://crisisofdemocracticstates.blogspot.fi/

http://crisisofdemocracticstates.blogspot.fi/p/what-kind-of-lifeforms-might-be-live-on.html

The imagination is always freedom for thinking, so don't be so serious about those things.

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http://crisisofdemocracticstates.blogspot.fi/p/the-imagination-is-always-freedom-for.html