It is highly recommended that you use Turbo Warp (see the Notes and Credits). Use the bar at the top of the screen to select one of three types of baryons. Click on the screen to place a baryon of that type. Press or hold down "x" while hovering over particles that you wish to delete. Press "c" to center the camera on the particles. Hold down "c" to continually track the center of mass of the particles (useful for assembling structures). Press "r" to spawn a random particle into the world, and hold down "r" to continually spawn random particles. The blue-type baryon is the negatively charged contron (or defteron), and is a fictional particle I made up. The yellow-type baryon is the positively charged proton. The red-type baryon is the neutrally-charged neutron (it does not interact with the electromagnetic field at all). The fourth type of baryon (grey) is another fictional particle I call the exaleipson, and it rapidly expends mass before vanishing from existence. This particle does not interact with other baryons, and likewise, baryons do not interact with it. Particles can decay into exaleipsons (the method of deletion). This project computes the effect of the electromagnetic force between all charged particles in the system. Each nucleon can only have a charge of ±1. The net force imparted by the EM force is computed here by Coulomb's law. This project also computes the effect of the nuclear force on all baryons in the system (formally the sum of all possible forces imparted on the baryons by transferring the gauge bosons of the strong force, virtual particles called gluons, which are not pictured here). The effect of the strong force is felt across all baryons, and is responsible for their clumping into nuclei. The strong force is computed here via the Reid potential (1968) assuming spins of all baryons in the system are aligned (to simplify calculations).
USE TURBO WARP: https://turbowarp.org/546913685/fullscreen?fps=60&hqpen&offscreen&limitless
