schizo comment

@@WonderfulDeath I have an electrical engineering and physics background. If you have developed the means to alter the electromagnetic density of a contiguous volume of space, I'm all ears. Or you're free to point out shortcomings of our ExB first device from last year, as I described it in the comment you replied. Or here's a challenge. I know the technical details of the device was deployed in the November 4, 1957 Fort Itaipu, Brazil incident that 'heated up' the two sentries in the incident. It was originally conceived by Tesla, then perfected by germans in the 1930s and 1940s. Do you know the technical details of that device? There you go, three challenges. Are you up to it? .

@@Greg_Chase i also have an engineering and physics background; don't care about your two latter challenges because they're not relevant, but there's many ways to alter the elctromagnetic density of a space. here's 10 ways, Electric Field Manipulation: By applying electric fields using electrodes or charged surfaces, you can influence the distribution of charged particles (ions and electrons) in space. This alters the electromagnetic density. Magnetic Field Manipulation: Similarly, manipulating magnetic fields using coils or permanent magnets can affect the motion of charged particles and hence the electromagnetic density. Electromagnetic Radiation: By emitting electromagnetic radiation (such as microwaves, radio waves, or light), you can introduce energy into the space, potentially altering the density of electromagnetic fields. Plasma Generation: Creating a plasma-a state of matter where atoms are ionized-can significantly alter electromagnetic properties. Plasma can be generated by heating gases or by applying high-voltage electric fields. Metamaterials: These are artificial materials engineered to have properties not found in naturally occurring substances. Metamaterials can be designed to manipulate electromagnetic waves, allowing for control over electromagnetic density in specific ways. Superconductors: Superconductors can expel magnetic fields (Meissner effect) and guide electromagnetic fields with extremely low loss. By incorporating superconducting materials, you can control electromagnetic density with high efficiency. Photonic Crystals: These are periodic structures that can control the flow of electromagnetic waves similarly to how semiconductor crystals control the flow of electrons. Photonic crystals can manipulate electromagnetic waves at the nanoscale. Dielectric Materials: By placing dielectric materials (insulators) in the space, you can alter the distribution of electric fields, affecting electromagnetic density. Waveguides and Resonators: These are structures designed to confine and control electromagnetic waves. By adjusting their geometry and material properties, you can manipulate the density and propagation of electromagnetic fields. Quantum Effects: Quantum phenomena such as quantum tunneling or the Casimir effect can influence electromagnetic properties at very small scales, providing avenues for controlling electromagnetic density.

@@WonderfulDeathNone of those methods can be used to create an acceleration field in a contiguous volume of space. I'm not saying there's anything wrong with that. It's certainly not taught. There are not degree tracks in artificial gravity. And by 'artificial gravity' I"m not referring to simulated gravity by way of rotating devices/centrifugal force. I think someone like you though, were it taught, might have pursued the topic. Good luck to you.

@@Greg_Chase you didn't ask for "an acceleration field in a contiguous volume of space" you asked for "the means to alter the electromagnetic density of a contiguous volume of space" which all of those methods can be used to create that, you shifted the goalpost. i don't think there is a viable way to create artificial gravity besides rotating devices, and even rotating devices are so impractical that the ISS refused to use them and instead had the astronauts acclimate to a zero gravity environment instead