• Boddhisatva@lemmy.world
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    6 months ago

    Temperature is a measure of kinetic energy at the molecular/atomic level. That said, the gasses falling into a black hole would likely reach such hypothetical temperatures as they near the event horizon.

    • Hamartiogonic
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      6 months ago

      But what about cutting steel with a plasma torch? Could you see macroscopic results of particles doing counterintuitive quantum stuff?

      • count_of_monte_carlo@lemmy.worldM
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        6 months ago

        Certainly! You can see discrete emission lines from the ionized air molecules, which only occurs because of quantum physics. I realize that’s not what you’re asking though.

        I did a quick calculation and for a plasma torch (~27000 Kelvin) and assuming air molecules, the average velocity of the plasma ions would only be like 6000 m/s. That’s 0.001% the speed of light, so you aren’t going to see any relativistic effects.

    • FlowVoid@lemmy.world
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      6 months ago

      Not necessarily. In fact, it’s possible for gravity at the event horizon to be less than Earth’s gravity.

        • FlowVoid@lemmy.world
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          6 months ago

          Gravity at the event horizon is inversely related to the mass of the black hole. So for a supermassive black hole, gravity at the event horizon can be weak. But you still can’t escape because it’s too large.

          Imagine light trying to escape the Earth’s gravity. Its path is slightly deviated by the Earth, then it gets far enough away that the Earth has little further effect.

          Now suppose at that distance, it still experienced the same gravity. So the trajectory of light is deviated a little more. It keeps moving farther away but gravity barely changes, even at huge distances. Eventually all those little deviations add up and it’s going back where it came from. Light can’t escape. It’s a black hole.