![Figure 1: A schematic representation of the reaction kinetics of Model G, a model based on the Brusselator with an extra G component.[1]](https://www.researchgate.net/profile/Brendan-Darrer/publication/363671056/figure/fig1/AS:11431281085193465@1663660734458/A-schematic-representation-of-the-reaction-kinetics-of-Model-G-a-model-based-on-the_Q320.jpg)
![Figure 2: Spherically-symmetric 3D stationary particle shown in 1D. Here, we see a fully formed stabilised neutral subatomic particle, taken from a video that simulates Model G's open reaction-diffusion system of X, Y and G substrates. This simulation does not include vortical motion of the substrates.[2]](https://www.researchgate.net/profile/Brendan-Darrer/publication/363671056/figure/fig2/AS:11431281085170804@1663660734539/Spherically-symmetric-3D-stationary-particle-shown-in-1D-Here-we-see-a-fully-formed_Q320.jpg)
September 2022
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A question for Stackexchange chemistry to raise awareness and feedback on SQK. Could reaction-diffusion processes taking place at the subquantum level lead to an accurate description of the same phenomena that quantum mechanics deals with? I.e. Can physical fields be explained by concentration patterns of tiny sub particle units, that engage in molecular-like reaction-diffusion processes? The Model G Vortical Motion Group comprises of a group of scientists working on a Subquantum Kinetics/Model G project. We work with a system called Model G which mathematically represents reaction-diffusion processes taking place in a space-filling ether. This approach follows a format similar to that of the Brusselator, but which is applied to microphysics rather than to chemistry. We aim to represent particle spin magnetic moment by simulating vortex currents in a subquantum reaction-diffusion ether substrate which is hypothesized to spawn a subatomic particle as a dissipative soliton. The ether we propose is multifarious in composition and transformative in nature , undergoing reactive interconversions, and is different from the historical ether *