• Chrobin@discuss.tchncs.de
    link
    fedilink
    English
    arrow-up
    11
    ·
    6 months ago

    Actually a good point, tho. And also a good thought: If there is no special direction, what would be up? And that’s where quantum mechanics gets even weirder: It’s either up or down in the direction you measure.

    • i_love_FFT
      link
      fedilink
      English
      arrow-up
      8
      ·
      edit-2
      6 months ago

      It’s either up or down whatever the direction.

      If you measure 100%up-0%down then you rotate your frame of reference by 90°, you automatically get 50%up-50%down… (iirc)

      It’s weirdly teasing us like that!

      • Ziglin@lemmy.world
        link
        fedilink
        English
        arrow-up
        8
        ·
        edit-2
        6 months ago

        Just in case it wasn’t clear you can’t measure anything other than “100%” up or down spin. The quantum state of it being 50/50 is described by 1/sqrt{2} times the up and down vector, when you measure it you have a probability of getting either result calculated by the square of the absolute (||psi||^2) that way you avoid getting a complex probability.

        btw I was too scared to try in case it doesn’t but can I use LaTeX in Lemmy comments? $\psi$ Edit: No LaTeX doesn’t seem to work and btw I didn’t study this so it might be taught differently at uni. This was explained to me in/for the context of quantum computing.

        • i_love_FFT
          link
          fedilink
          English
          arrow-up
          3
          ·
          6 months ago

          True! Thanks for the clarification, it’s been a while since i played with the maths of quantum physics!

          After you measure a spin as 100% up, the state will be close to that for a while, si the next measurement has higher chance of being up, with this probability slowly decreasing with time.

          • Ziglin@lemmy.world
            link
            fedilink
            English
            arrow-up
            1
            ·
            6 months ago

            I think that assuming the particle has no (extra?) energy it’s state does stay the same. That is of course not possible in real life though but the <20 millikelvin in some quantum computers get pretty close.

            Also I think nobody says they measure it as 0/100% up, They just say up or down in my limited experience.

            Does anyone have any good resources on quantum mechanics? (Most of my information comes from a few professors) There’s some useful stuff on chem libretexts (I think that’s what it’s called) for simple wave functions, but it doesn’t seem perfect.

            • i_love_FFT
              link
              fedilink
              English
              arrow-up
              1
              ·
              6 months ago

              I have old college textbooks in my library, Cohen-Tannoudji. I’m not sure about online resources though…

    • Ziglin@lemmy.world
      link
      fedilink
      English
      arrow-up
      3
      ·
      6 months ago

      At least in the Stern-Gerlach experiment it’s relative to the magnetic field.