Quenched random growth rates make FKPP fronts travel faster on average by a universal factor times the disorder variance and produce diffusive position fluctuations whose strength also scales with the square of the variance.
Effect of Microscopic Noise on Front Propagation
3 Pith papers cite this work, alongside 104 external citations. Polarity classification is still indexing.
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UNVERDICTED 3representative citing papers
In an idealized model, evolutionary adaptation speed peaks at intermediate selection pressure due to a phase transition where random effects overtake genetic fitness, illustrating a biological Goodhart's law.
Model indicates wild-type recolonization probability behind gene drive waves increases with lower drive fitness and smaller local carrying capacity.
citing papers explorer
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FKPP fronts in quenched random media
Quenched random growth rates make FKPP fronts travel faster on average by a universal factor times the disorder variance and produce diffusive position fluctuations whose strength also scales with the square of the variance.
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Selection of the fittest or selection of the luckiest: the emergence of Goodhart's law in evolution
In an idealized model, evolutionary adaptation speed peaks at intermediate selection pressure due to a phase transition where random effects overtake genetic fitness, illustrating a biological Goodhart's law.
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Stochastic dynamics at the back of a gene drive propagation wave
Model indicates wild-type recolonization probability behind gene drive waves increases with lower drive fitness and smaller local carrying capacity.