I don’t believe free will is real. I’m not a deep physics person (and relatively bad at math), but with my undergrad understanding of chemistry, classical mechanics, and electromagnetism, it seems most rational that we are creatures entirely controlled by our environments and what we ingest and inhale.

I’m not deeply familiar with chaos theory, but at a high level understand it to be that there’s just too many variables for us to model, with current technology, today. To me that screams “god of the gaps” fallacy and implies that eventually we WILL have sufficiently powerful systems to accurately model at that scale…and there goes chaos theory.

So I’m asking you guys, fellow Lemmings, what are some arguments to causality / hard determinism, that are rooted entirely in physics and mechanics, that would give any credit to the idea that free will is real?

Please leave philosophical and religious arguments at the door.

  • A_A@lemmy.world
    link
    fedilink
    arrow-up
    4
    arrow-down
    1
    ·
    1 year ago

    The double-rod pendulum is one of the simplest dynamical systems with chaotic solutions. …from Wikipedia

    This system is very simple yet even with initial conditions varying by (less than) Planck’s time or Planck’s length, theoretical resulting behavior changes after a few cycle.
    Physical determinism says that there cannot be creation of (new) information yet this system does exactly that.

    • intensely_human
      link
      fedilink
      arrow-up
      8
      ·
      1 year ago

      Also it should be pointed out that this doesn’t require indeterminacy to happen. A perfectly deterministic Newtonian model of the double pendulum will exhibit the chaotic behavior.

      It’s almost like if you put a black box around that pendulum, on which a light blinked each time the two pendula were parallel (ie when their joint was straight), the blinking of that light would seem “probabilistic”.

      And it would be unpredictable too. Despite a perfect, zero-fuzziness Newtonian model determining the pendulum’s behavior, it would be impossible to predict the blinking of the light.

      I’ve only had the briefest introductions to chaos theory but it’s fascinating.

      • NoneOfUrBusiness@kbin.social
        link
        fedilink
        arrow-up
        5
        ·
        1 year ago

        And it would be unpredictable too. Despite a perfect, zero-fuzziness Newtonian model determining the pendulum’s behavior, it would be impossible to predict the blinking of the light.

        Wait really? How?

        • intensely_human
          link
          fedilink
          arrow-up
          4
          ·
          1 year ago

          Basically a chaotic system is such that it tends to expand differences in path instead of shrink them.

          An example of a non-chaotic system is a cannonball fired at X1 speed and X2 angle in a gravitational field, where you measure the distance Y being how far it flies.

          You fire the cannon, the ball lands a little short of the target, so you know you can increase the firing velocity a bit and probably hit that target.

          If you overshoot, you shoot slower next time. If you undershoot, you shoot faster. (I’m not playing with the angle here because the angle is slightly weirder, too low and angle and you undershoot, but too high an angle and you also undershoot).

          So the relationship between the position of the muzzle speed knob, and the final position of the cannonball, follows a “linear” relation. If turning the knob 100 mph results in the cannonball landing 100 m away, and turning the knob 300 mph cresults in the cannonball being 500 m away, then because it’s a linear system you can reason that turning the knob 200 mph results in the cannonball being somewhere between 100 m and 500 m away.

          In short, given a function mapping points in one space onto points in another space, a linear function ensures that two points close on the input space will be close to two points in the output space.

          A chaotic function doesn’t preserve this. It scrambles the relationships between input and output. The lines between input points and output points cross each other; if they were hair they’d no longer be combed.

          Say you replace your empty sky with a giant 3D pinball machine, and then you fire cannonballs into that.

          You set the dial to 100 mph: cannonball lands 100 m away.
          You set the dial to 300 mph: cannonball lands 500 m away. you set the dial to 200 mph: where will it now?

          Because you’ve introduced the pinball machine to the sky, you can no longer predict that the cannonball is going to land between 100 and 500 meters away.

          Maybe the 100 mph cannonball went under a bumper, the 300 mph cannonball went over it, but the 200 mph cannonball hits it, and bounces back over your head and it lands behind you.

          Now you’ve got this table of inputs to outputs:

          | muzzle speed | landing position | | 100 mph | 100 m | | 200 mph | -750 m | | 300 mph | 500 m |

          (The choice to mix imperial and SI units is deliberate, by the way, because in real life these variables might have totally unrelated units. Like “value of a gram of gold in yen” “number of red blood cells passing into the brain per hour”. Nonlinearity isn’t a property specifically of space so I didn’t want it to look like it was an equation about space or distance)

          Anyway, I’m probably wrong about 20% of that but it’s my understanding of chaos.

          Now to your question:

          How [would it be unpredictable]?

          It relies on my assumption that there is an infinite amount of information in the positions and velocities of the particles.

          (This is probably false but I’m carrying the argument through anyway to see where it goes)

          In other words, that if you wrote the position or velocity of the particle it would take an infinite number of written digits to capture the position, or velocity, precisely.

          The chaos comes from this: when there’s no longer a relationship forcing points “between” each other to be “between” each other in the output, it happens at every level. (for math people: linear isn’t literally a line, but any complex polynomial with real number coefficients. I think? Maybe it’s no compound terms that makes it linear? Something like that.It’s been 20 years and I lost my old diff eq book). But it can be a very squiggly line and still be mathematically a “linear function”.

          Meaning that each input number is unpredictably related to the number next to it: 1’s relationship to 2 isn’t known. Whether 2 falls between 1 and 3 isn’t known.

          But surely 1.5 is between 1 and 2 right? Nope it happens in the first decimal place too.

          You might be able to predict the probability, because maybe the input can’t travel too far from the output. But after the system cycles, the positions are at least a little shuffled. And as time goes on, just the random shuffling will tend to move input lines further from each other.

          The end result is that tiny deviations in input become huge deviations in output, and 1.11342 might map to 100 while 1.11343 maps to 975, and 1.11344 maps to 42, and 1.113421 maps to 4,350.

          It’s like zooming into a fractal. Each tiny detail gets larger and larger and can move the entire thing.

          And it can even happen with finite input (though it does become literally predictable by simulation, but is still computationally irreducible).

          Shit I’m really bad at keeping things short.

          It’s like pointing a camera at a live feed of itself. If you haven’t seen it, try it or look it up on youtube.

          TL;DR: Tiny differences in input become huge differences in output in a chaotic system, meaning in a continuous universe imperfections too small to measure doom the prediction

          • CAPSLOCKFTW@lemmy.ml
            link
            fedilink
            arrow-up
            3
            ·
            1 year ago

            TL;DR: Tiny differences in input become huge differences in output in a chaotic system

            You’re missing a “can” there. Tiny differences in input can become huge differences in output in a chaotic system. (Infinitely) many chaotic systems are structurally stable. For example consider systems that have the Anosov property.

      • A_A@lemmy.world
        link
        fedilink
        arrow-up
        1
        ·
        1 year ago

        Hi @intensely_human
        You are the only one here who gets it easily even though I didn’t say much. Also in this tread I’m now up to 8 levels’ comments with @grabyourmotherskeys but we are getting nowhere & I am quite feedup. So if you could do something here I would appreciate.

        Thanks

    • grabyourmotherskeys@lemmy.world
      link
      fedilink
      arrow-up
      5
      ·
      edit-2
      1 year ago

      Here’s the thing. At what point does the causal chain get interrupted, free will kick in, and then the old causal chain fires back up? Because that’s what arguments like yours are implying.

      The response is always that I don’t understand the theory you have put forward. I’ll grant that.

      If the proof free will is tied to a seemingly stochastic system how is that “free will”. If I replaced your decision making with a random number generator would that be free will?

      I sincerely hope you will engage with me here.

      To be perfectly clear, my view is that we do not have free will but our limited set of information makes it seem like we do and so it is rational to continue on despite this. Put another way, I know the latest Mission Impossible movie was made months before I saw it, and that the outcome was predetermined, but wow, what a ride.

      • A_A@lemmy.world
        link
        fedilink
        arrow-up
        1
        ·
        edit-2
        1 year ago

        At what point does the causal chain get interrupted ( … ?)

        The system is diverging at every point in time :

        In chaotic systems, the uncertainty in a forecast increases exponentially with elapsed time. (… same article from Wikipedia)

        I believe one has to see this before being able to apply it to free will explanations.

          • A_A@lemmy.world
            link
            fedilink
            arrow-up
            1
            ·
            1 year ago

            at what point ( … ? )

            Before answering this I need to know if you get the basics : what do you understand so far ? About chaotic systems ? About their variable rate of exponential divergence ? About their “liberty” ? About the fact we have such systems in us, only far more complex ?

            And beyond any explanations, if you came to know we have free will, how could we stand the shame and guilt of not doing enough ?

              • A_A@lemmy.world
                link
                fedilink
                arrow-up
                2
                ·
                1 year ago

                It’s something I think about constantly, whether I want to or not! ;)

                When I was young I was in that situation, with those same questions. But I was lucky : I had the right science and the right IQ and I found the answers. You are now thirsty and I gave you some salt ; if you are too blind to see it or too arrogant, bad for you, so i will not come back to this.

                Goodbye.

                • grabyourmotherskeys@lemmy.world
                  link
                  fedilink
                  arrow-up
                  1
                  arrow-down
                  1
                  ·
                  edit-2
                  1 year ago

                  You still haven’t answered the question and have made at least a couple of inferences about me that aren’t really accurate.

                  Anyway, people say it you can’t explain it you don’t understand it

                  Edit: sorry, wrong thread. I would still say you are making lot of assumptions.

                  How old do you think I am? Let’s start with that. :)