Temperature, the universe's expansion, and radiation

If the energy level of a particle is precisely the same as its environment, it is invisible. 

Temperature is the energy level. But it's also the size of the particle. When a particle's energy level rises its size turns smaller. In that case, the particle's shell's surface area will increase in comparison to the volume of the particle. And that thing means it sends more radiation out than low-energy particles. 

When the size of the particle increases that thing means that its surface in comparison with its volume decreases. That means the cold particle can keep energy inside it better than the small particle. But then, of course, energy travels out from high-energy particles faster than low-energy particles because the energy transfer speed depends on the difference between the particle and its environment. 

When we think that energy hits a particle from outside and then it travels in the middle of it, it forms a standing wave in the middle of the particle. When the standing wave that causes reflection is closer to the shell of the particle it pushes that shell harder. Because the particle is a whisk-looking structure. That means some part of that wave movement travels out from the particle between those superstrings. 

The image above originally portrays the neutron star. But it could portray some elementary particle. The elementary particle is like a whisk-looking structure or quantum lightning. That is forming around the stick-looking structure. Could that structure be from around the wormhole? 

Do the particles form around extremely small wormholes? 

But then we can think that the particle is like a whisk or onion, that forming around some stick-looking structure. So that thing means that the structure that forms those superstrings or quantum flashes of lightning around it is some kind of wire that travels through the universe. That structure can be a wormhole. Or the quantum tornado that makes it possible, that material can form around it. In this case, the material is the ball-shaped power field that is forming around the central axle. 

When we look at the model of the Higgs field there is a small lower energy area around that particle, which is like the hill in the sombrero-looking thing. The reason for that lower energy area is that there is an electromagnetic shadow around that particle. When electromagnetic wave movement travels over that valley it loses part of its energy. 

Or some part of that lower energy area is that the quantum lightning or superstrings are forming the shadow also inside the particle's whisk-looking shell. Those electromagnetic shadows also transfer energy or wave movement out from the particle. 

But then, if the temperature or the particle's energy is precisely the same as its environment. The particle turns invisible. There is no energy transfer between particles and their environment. If their energy level is the same. The reason. These kinds of things are hard to make in real life and can be found in cosmic expansion. 

Because the universe expands all the time, its energy level decreases. That means the quantum fields that are pressing particles to lose their power. And then the particle sends wave movement. Theoretically is possible to make the material that is invisible if we can predict the cosmic expansion and the power of impacting electromagnetic radiation. If the energy level of the material can stabilize to the same level as its environment the material turns invisible in every electromagnetic frequency.