• Limitless_screaming@kbin.social
      link
      fedilink
      arrow-up
      28
      ·
      1 year ago

      If you have two charges q1 and q2, you can get the force between them F by multiplying them with the coulomb constant K (approximately 9 × 10^9) and then dividing that by the distance between them squared r^2.

      q1 and q2 cannot be negative. Sometimes you’ll not be given a charge, and instead the problem will tell you that you have a proton or electron, both of them have the same charge (1.6 × 10^-19 C), but electrons have a negative charge.

      • pewter@lemmy.world
        link
        fedilink
        arrow-up
        18
        ·
        1 year ago

        q1 and q2 can be negative. The force is the same as if they were positive because -1 x -1 = 1

        • Limitless_screaming@kbin.social
          link
          fedilink
          arrow-up
          4
          ·
          1 year ago

          In this case yes, but if q1 was -20μC, q2 was 30μC, and r was 0.5m, then using -20μC as it is would make F equal to -21.6N which is just 21.6N of attraction force between the two charges.

          • Pelicanen
            link
            fedilink
            arrow-up
            5
            ·
            1 year ago

            If they are oppositely charged particles, I would expect that there is a force of attraction acting on them, yes.

        • Pinklink@lemm.ee
          link
          fedilink
          arrow-up
          1
          arrow-down
          1
          ·
          edit-2
          1 year ago

          But that if both are negative not one pos one neg like the previous commenter gave in their examples, so the true formula has an absolute value in the numerator: |q1Xq2|

    • Arthur_Leywin@lemmy.ml
      link
      fedilink
      arrow-up
      11
      ·
      edit-2
      1 year ago

      G is a constant,

      m is mass,

      d is distance from each other starting from their center of mass,

      This measures gravitational force, F