A stochastic analysis of the growth of competing microbial populations in a continuous biochemical reactor

DOI10.1016/0025-5564(79)90098-1zbMath0449.92018OpenAlexW2042991120MaRDI QIDQ1147653

Publication date: 1979

Published in: Mathematical Biosciences (Search for Journal in Brave)

Full work available at URL: https://doi.org/10.1016/0025-5564(79)90098-1

zbMATH Keywords

Fokker-Planck equation steady state numerical solutions dilution rate initial value transition probability density continuous biochemical reactor growth of competing microbial populations

Mathematics Subject Classification ID

Nonlinear ordinary differential equations and systems (34A34) Population dynamics (general) (92D25) Applications of Brownian motions and diffusion theory (population genetics, absorption problems, etc.) (60J70) Numerical methods for partial differential equations, initial value and time-dependent initial-boundary value problems (65M99)

Related Items (27)

Long run coexistence in the chemostat with multiple species ⋮ Steady-state coexistence of three pure and simple competitors in a four- membered reactor network ⋮ Noise-induced stochastic transition: a stochastic chemostat model with two complementary nutrients and flocculation effect ⋮ Bounded random fluctuations on the input flow in chemostat models with wall growth and non-monotonic kinetics ⋮ Coexistence of three competing microbial populations in a chemostat with periodically varying dilution rate ⋮ Coexistence in chemostat-like models ⋮ A regime switching model for species subject to environmental noises and additive Allee effect ⋮ Study of the dynamics of two chemostats connected by Fickian diffusion with bounded random fluctuations ⋮ Gaussian approximations for chemostat models in finite and infinite dimensions ⋮ Stochastic characteristics and optimal control for a stochastic chemostat model with variable yield ⋮ A stochastic analysis of the growth of competing microbial populations in a continuous biochemical reactor ⋮ Asymptotic behavior of a chemostat model with stochastic perturbation on the dilution rate ⋮ How can inter-specific interferences explain coexistence or confirm the competitive exclusion principle in a chemostat? ⋮ Delay induced oscillations in a turbidostat with feedback control ⋮ Study of the chemostat model with non-monotonic growth under random disturbances on the removal rate ⋮ ASYMPTOTIC BEHAVIOUR OF THE STOCHASTIC MAKI–THOMPSON MODEL WITH A FORGETTING MECHANISM ON OPEN POPULATIONS ⋮ The growth of pure and simple microbial competitors in a moving distributed medium ⋮ Break-even concentration and periodic behavior of a stochastic chemostat model with seasonal fluctuation ⋮ Practical coexistence of two species in the chemostat -- a slow-fast characterization ⋮ Coexistence of three microbial populations competing for three complementary nutrients in a chemostat ⋮ Oscillations of two competing microbial populations in configurations of two interconnected chemostats ⋮ Exclusion and persistence in deterministic and stochastic chemostat models ⋮ Coexistence of two microbial populations competing for a renewable resource in a non-predator-prey system ⋮ On the coexistence of three microbial populations competing for two complementary substrates in configurations of interconnected chemostats ⋮ On Geometry and Scale of a Stochastic Chemostat ⋮ Cell mass concentration variance resulting from fluctuations in the incoming nutrient concentration to a chemostat ⋮ Periodic, quasi-periodic, and chaotic coexistence of two competing microbial populations in a periodically operated chemostat

Cites Work

This page was built for publication: A stochastic analysis of the growth of competing microbial populations in a continuous biochemical reactor