(To be clear, I’m more interested in the reach and scaling of gravity.)

If we were to suddenly double earth’s mass, but not it’s size, would it’s field double in size (I assume strength as well), to the extent that if I were to measure this increased gravity at the same place I measured earth’s normal gravity, it would simply be double? If so, the least measurable point of both gravitates should also be the same?

Just wondering if there’s diminishing returns or if mass and density affects a gravity field the same regardless of whether it’s an asteroid or a billion Solar Masses.

Feel free to share any views I’m not taking into account in regards to gravity fields.

Thanks

  • Jeredin@lemm.eeOP
    link
    fedilink
    English
    arrow-up
    1
    arrow-down
    1
    ·
    1 year ago

    This was the answer I was after, thank you!

    Additional question that’s related, if you’d like to try it: I’ve read about vacuum energy/zero point energy - hawking radiation exists because of those theories. From what I’ve read, vacuum energy has the potential for any form of matter but because of the uncertainty principle, less likely to produce higher forms of energy, and thus why most fluctuations produce only virtual particles. My main question then is: so no matter what, all of space ether has matter or potential for matter? If so, should a photon actually collide with a virtual particle it would actually stay in physical existence)?

    Thank again

    I would assume I’m not interested in any of the associated crackpot ideas some have.

    • FlowVoid
      link
      fedilink
      English
      arrow-up
      2
      ·
      1 year ago

      If a photon collides with a particle, virtual or not, then the particle will eventually emit another photon.