https://merlinpelz.carrd.co 2026-04-02 daily 1.0 https://merlinpelz.carrd.co/assets/images/image01.jpg https://merlinpelz.carrd.co/assets/images/gallery01/12e04ac4.jpg Symmetry-breaking in periodic 1-D domain with two compartments with FitzHugh-Nagumo kinetics. © Merlin Pelz https://merlinpelz.carrd.co/assets/images/gallery01/d7b870ce.gif Convergence to symmetry-broken state in periodic 1-D domain with two compartments with Rauch-Millonas kinetics. © Merlin Pelz https://merlinpelz.carrd.co/assets/images/gallery01/d92315f3.jpg Convergence to asymmetric state for which one cell is up- and two cells downregulated ("silenced") in periodic 1-D domain with cell Gierer-Meinhardt reaction kinetics. © Merlin Pelz https://merlinpelz.carrd.co/assets/images/gallery01/4d1ba298.jpg Bifurcation diagram showing degenerate pitchfork bubble in which stable symmetry-breaking takes place, no-flux 2-D domain with two Rauch-Millonas cells. Hysteresis occurs. © Merlin Pelz https://merlinpelz.carrd.co/assets/images/gallery01/0355be31.jpg Asymmetric steady-state in no-flux 2-D domain with two diffusion-coupled Gierer-Meinhardt cells. © Merlin Pelz https://merlinpelz.carrd.co/assets/images/gallery01/b7bc9f6a.jpg Numerical experiment: pattern formation in the no-flux 2-D domain with three big and close diffusion-coupled cells with Gierer-Meinhardt reaction kinetics. © Merlin Pelz https://merlinpelz.carrd.co/assets/images/gallery01/5c2fc7cd.jpg Convergence to stochastic attractor after stochastic bifurcation point in periodic 1-D domain with two nonlinearly randomly perturbed Rauch-Millonas cells. © Merlin Pelz https://merlinpelz.carrd.co/assets/images/gallery01/fd974e77.jpg Extracellular diffusivity as bifurcation type parameter for phase transition of a Kuramoto order parameter for synchronization in system with two cells with oscillatory intracellular kinetics in ℝ² © Merlin Pelz https://merlinpelz.carrd.co/assets/images/gallery01/9b23b952.jpg Synchronization of 4 equally separated cells with oscill. intracellular Sel'kov reaction kinetics in ℝ². Only cells 1 & 3 would oscillate if they were alone, but in the cell group cells 2 & 4 oscillate heavily. This is more than usual _quorum sensing_. ©MP