Skip to main content

The antigravitation and gravitational waves



Gravitational waves can be the key to real antigravitational systems. 


The formation of a gravitational wave may provide an answer for so-called "real" antigravitation. The supernova explosion or collision of the super heavy objects is forming an energy load that can explain gravitational waves. When that radiation with ultra-high energy level hits the particles it forms an electromagnetic or quantum shadow on the opposite side of the particles. 

Energy flows to that shadow and moves the particle away from the gravitational wave source. But if we want to make a "real" anti gravitation system we must be more accurate. When wave movement from the source of the gravitational waves impacts the quantum field of particles, it slides over that quantum field. 

The reason why gravitation pulls objects is that something makes the particles act like small rocket engines. So something causes an asymmetry in the energy flow from the objects in a gravitational wave. 

The surfer who rides with the waves is between two quantum systems. The particle in space is surrounded by one quantum system. So when we are researching gravitational waves. We should compare them with underwater pressure waves rather than surface waves. 

When we think of gravitational waves and compare them with the regular waves we might think that material is like a surfer which rides by using those waves. If the surfboard is at the edge of a wave peak that gives the best experience. The reason for that is the airflow gives extra energy to the surfer and the board. 

We cannot compare the objects in the space to the surfer. The reason for that is simple. The material and particles in the universe are in 3D space. So they are surrounded by one quantum system. The surfer is on the edge of two quantum systems. So if we want to model the behavior of the objects in gravitational waves we should use submerged objects for that model. 

In the quantum mechanics particle is the thing that rides with gravitational waves like surfer rides with waves. The water is the quantum system as well as the air. That is a simplified way to say that thing. We should rather say, that the submerged particle is riding with an underwater pressure wave when we are researching gravitational waves. 

When a surfer rides that wave the energy of the wave hits the surfer. And the energy stability causes the energy level of the surfer and wave to be the same. Energy travels between participants of the quantum system until it reaches stability. And that means all participants of the system have the same energy level. But air and water are different quantum systems. When the nose of the surfboard goes over the edge of the wave. That brings energy from another quantum system. And that thing causes that best ride is in that special place. 

But if we want to research the behavior of the object in a gravitational wave. We must understand that the object is in the 3D space. And in that case, we must research underwater objects. The reason why a surfer who rides the wave gets a better ride than that scuba diver who is below the surface is that the energy flows from another quantum system. When the object is underwater. There are no other quantum systems than water. 

So when the object is underwater it is surrounded by the same quantum system. That thing causes that even if the waves are high. There is calm in underwater conditions. 


The wave is the energy load that impacts that object. 


Wave movement doesn't connect straight behind the particle, or its quantum field. And that thing moves particles. When electromagnetic wave movement hits the quantum field of the particle it slides over it. 

There is forming a small electromagnetic vacuum behind that particle. Which stretches its quantum field. And that causes lower pressure on the other side of the gravitational wave. 

That causes that material or particle inside that field sends extra photons to that point. So the electromagnetic low pressure causes the punch behind the gravitational wave will turn higher than impacting energy. And that causes the thing called gravitation. 

But the question is this: does that electromagnetic wave movement cause the shape of the quantum field to change? Or does the electromagnetic or quantum vacuum form behind the particle itself? In the last case, the wave movement passes the quantum field and impacts to particle that is inside it. The place of the particle is always the middle of the quantum field. And when its place is moving the quantum field also moves. 


So how to make the antigravitational system?


The idea is simple in theory. There is needed to make the electromagnetic wave movement that tunnels itself through the material. The system must base the idea that the radiation comes from upside. Will stretch the electromagnetic or quantum fields around the particles of the atoms and other particles. 

Then that thing causes particles that are in that radiation shower to send photons to the side where is electromagnetic low pressure in their stretching quantum fields. And that thing turns the energy flow asymmetrical. So the higher power of the energy is forming behind that material or plate. And that thing pushes the object upward. 


https://miraclesofthequantumworld.blogspot.com/


Comments

Popular posts from this blog

The new bendable sensor is like straight from the SciFi movies.

"Researchers at Osaka University have developed a groundbreaking flexible optical sensor that works even when crumpled. Using carbon nanotube photodetectors and wireless Bluetooth technology, this sensor enables non-invasive analysis and holds promise for advancements in imaging, wearable technology, and soft robotics. Credit: SciTechDaily.com" (ScitechDaily, From Sci-Fi to Reality: Scientists Develop Unbreakable, Bendable Optical Sensor) The new sensor is like the net eye of bugs. But it's more accurate than any natural net eye. The system is based on flexible polymer film and nanotubes. The nanotubes let light travel through it. And then the film at the bottom of those tubes transforms that light into the image. This ultra-accurate CCD camera can see ultimate details in advanced materials. The new system can see the smallest deviation in the materials.  And that thing makes it possible to improve safety on those layers. The ability to see ultra-small differences on surf

Quantum breakthrough: stable quantum entanglement at room temperature.

"Researchers have achieved quantum coherence at room temperature by embedding a light-absorbing chromophore within a metal-organic framework. This breakthrough, facilitating the maintenance of a quantum system’s state without external interference, marks a significant advancement for quantum computing and sensing technologies". (ScitechDaily, Quantum Computing Breakthrough: Stable Qubits at Room Temperature) Japanese researchers created stable quantum entanglement at room temperature. The system used a light-absorbing chromophore along with a metal-organic framework. This thing is a great breakthrough in quantum technology. The room-temperature quantum computers are the new things, that make the next revolution in quantum computing. This technology may come to markets sooner than we even think. The quantum computer is the tool, that requires advanced operating- and support systems.  When the support system sees that the quantum entanglement starts to reach energy stability. I

Humans should be at the center of AI development.

"Experts advocate for human-centered AI, urging the design of technology that supports and enriches human life, rather than forcing humans to adapt to it. A new book featuring fifty experts from over twelve countries and disciplines explores practical ways to implement human-centered AI, addressing risks and proposing solutions across various contexts." (ScitechDaily, 50 Global Experts Warn: We Must Stop Technology-Driven AI) The AI is the ultimate tool for handling things that behave is predictable. Things like planets' orbiting and other mechanical things that follow certain natural laws are easy things for the AI. The AI might feel human, it can have a certain accent. And that thing is not very hard to program.  It just requires the accent wordbook, and then AI can transform grammatically following text into text with a certain accent. Then the AI drives that data to the speech synthesizer. The accent mode follows the same rules as language translation programs. The ac