The atom model with the electrons going around the nucleus, is inspired by the solar system. The better model doesn’t look anything alike. This is a naturalistic circular fallacy
If atoms were like the solar system, all of the electron orbits would lose energy and decay by emitting electromagnetic radiation.
The same type of decay does occur in the solar system as the planets emit gravitational radiation, but the decay rate is so miniscule we can’t really detect it.
Could you explain what you mean by “emitting gravitational radiation”? Gravity is how we perceive distortions in spacetime, the strength of which being determined by the mass of the objects. I understand that orbits can “decay”, but that is not the same as radioactive decay.
General relativity is famously difficult to understand, and I don’t claim to fully understand it, so I’m going to fall back to the famous rubber sheet model.
Imagine the Earth in empty space. The mass of the Earth causes spacetime curvature that extends outward away from the Earth. However, if you look a single little patch of spacetime at some distance, say, 1000 km away, that little patch doesn’t know that it has to be curved because the Earth is 1000 km away. It doesn’t know where the Earth is. It just knows that its neighboring patch is a little bit more curved in the direction that leads to Earth, and its other neighbor is a little bit less curved going away from Earth. This essentially restates the principle of locality: all physics is local physics, and there is no spooky action at a distance.
Now imagine that the Earth moves by some small distance dx in a small time dt. Going back to our little patch of spacetime, it doesn’t know that the Earth moved. So how does it change its curvature to match the new position of the Earth? It changes when its neighbors change. When the Earth moves, the spacetime immediately near the Earth stretches and bends first, then spacetime a little further away, and so on and so on. This process doesn’t happen instantaneously; it takes time for changes to propagate to longer distances. The theory predicts that disturbances and ripples will propagate via waves, called gravitational waves, and that these waves travel at the same speed of light as electromagnetic waves.
Notice I called these spacetime waves “gravitational waves.” It is common to use the term “gravity waves” for typical water waves, of the kind you might see at the beach. Those are not the same type of wave.
Now let’s talk about energy. The Earth in the solar system has some energy, including translational and rotational kinetic energy, gravitational potential energy as it sits in the Sun’s gravity well, and of course its own thermal energy and rest mass. Waves have the ability to transport energy from one location to another without transporting matter, mass, or electric charge. Spacetime waves are not any different. Because the Earth is moving in a periodic motion, it produces a periodic spacetime wave that propagates outward away from the solar system, and that spacetime wave carries some amount of energy away from the solar system. Where does that energy come from? It comes from the Earth, mainly from the Earth’s kinetic energy.
So the story is that the gravitational waves are very, very, very slightly causing the Earth to slow down in its orbit. And following the laws of orbital mechanics, this causes the Earth to fall closer to the Sun. The result is that over the long term, the radius of the Earth’s orbit gets smaller. Alternatively, the Earth’s circular orbit is an illusion, and it’s actually spiraling inward on a very, very, tightly packed spiral. That’s what I meant by “orbital decay.”
I find it hard to overstate just how small this gravitational radiation effect is for a typical solar system situation. We have an observatory called LIGO that can detect gravitational waves. It can measure a variation in distance of a tunnel of several kilometers down to well less than a single proton diameter. (Remember, this is trying to detect disturbances in space and time itself). Even still, it is only able to detect gravitational waves from the most powerful kinds of gravitational events–mergers of black holes and the like.
Essentially: Spacetime is very “stiff” and gravity is very weak.
They weren’t talking about radioactive decay, electrons are stable. They were talking about electrically charged particles emitting electromagnetic radiation when accelerated. (Circular movement is accelerated, see centripetal force) Since they use energy for this, they would very quickly fall into the nucleus (if I remember correctly, in around 10^-14 s).
Bodies with mass also emit gravitational waves when accelerated, but much less.
Electrons do orbit like planets in the solar system however they’re also waves. Which is what gives the set radii they can orbit at and keeps it all stable. The orbits can and do change due to the emission or absorption of certain quanta of radiation.
So saying like is fine. It’s not an exact description but more of a simile to help understanding. They do orbit like a solar system. Saying electrons orbit the same as a solar system would be incorrect. That’s when the maths doesn’t work and the electrons orbit would decay.
that is not what i’ve learned, afaik electrons do not orbit with any sort of movement, and in fact talking about positions and movements at all on such a small scale is misleading.
What i’ve learned is that electrons exist as a probability cloud, with a certain chance to observe them in any given position around the atom depending on the orbital and the amount of other electrons.
Comparing it to gravitational orbits is just basically entirely incorrect, and certainly isn’t going to help someone pass advanced physics classes.
Ok, hear me out for curiosity sake. What happens if you slow down time to magnitudes less then you can observe?
What if we’re all wrong and the Paulie exclusion principle is just electrons clearing their orbit of debris (sub electrons). Also, for the heaviest elements the outer shell is actually populated by dwarf-electrons. And electron sharing in molecules is just Oort Cloud stuff somehow. And our galaxy is a virus. And our bodies are a battleground. And humans are just batteries. Whait a minute —
Yes, because everybody knows the earth is in the sun’s p orbital
I stand corrected. I should have checked; I mean, I’m not a quantum astrophysicist.
Honestly the visual representation of the atom is just a simplified artist’s rendition. It’s more acceptable to treat the atom’s components as charge fields filled with very high energy contained by nuclear forces. That said, the planets with molten cores and the sun also have their own electromagnetic fields so maybe the concept isn’t so far off.
There was a guy on the net years ago who claimed that the entire universe is an electron on a plutonium atom. He made a religion out of it, wrote hymns to the atom (or, more precisely, changed the words of Christian hymns, clumsily fitting in references to plutonium atoms) and even legally changed his name to Archimedes Plutonium.
I always find it fascinating how specific those theories become. Want to believe that our universe is just some sort of quark in a bigger universe we can’t know anything about? Fine. Doesn’t make terribly much sense, but what does at that scale anyway? But then going on and being sure that that bigger thing must be Plutonium? Why? How?
Look, I’m not saying our universe exists as a node in an infinite fractal of repeating universes, but one of these is the largest structure we can see and another is the smallest:
“Quod est superius est sicut quod inferius, et quod inferius est sicut quod est superius.”
“That which is above is like to that which is below, and that which is below is like to that which is above.”
First time I heard of this, super neat, thanks for sharing. Found a good article here:
What is the average length of something very small (Plank length, electron penis, whatever) and the biggest thing (observable universe distance, actual universe length) ?
