Search results for "92C40"

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The minimal model of Hahn for the Calvin cycle.

2018

There are many models of the Calvin cycle of photosynthesis in the literature. When investigating the dynamics of these models one strategy is to look at the simplest possible models in order to get the most detailed insights. We investigate a minimal model of the Calvin cycle introduced by Hahn while he was pursuing this strategy. In a variant of the model not including photorespiration it is shown that there exists exactly one positive steady state and that this steady state is unstable. For generic initial data either all concentrations tend to infinity at lates times or all concentrations tend to zero at late times. In a variant including photorespiration it is shown that for suitable v…

LightExistential quantificationMolecular Networks (q-bio.MN)02 engineering and technologyDynamical Systems (math.DS)Mathematical proofBiochemistryModels BiologicalMinimal modelsymbols.namesakeAdenosine Triphosphate0502 economics and business0202 electrical engineering electronic engineering information engineeringFOS: MathematicsApplied mathematicsQuantitative Biology - Molecular NetworksMathematics - Dynamical SystemsPhotosynthesisMathematicsCompactification (physics)Applied Mathematics05 social sciencesGeneral MedicineCarbon DioxideOxygenComputational MathematicsKineticsGlucoseModeling and SimulationFOS: Biological sciencesPoincaré conjecturesymbols020201 artificial intelligence & image processingGeneral Agricultural and Biological Sciences92C40 34C60050203 business & managementAlgorithmsMathematical biosciences and engineering : MBE
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Overload breakdown in models for photosynthesis

2015

In many models of the Calvin cycle of photosynthesis it is observed that there are solutions where concentrations of key substances belonging to the cycle tend to zero at late times, a phenomenon known as overload breakdown. In this paper we prove theorems about the existence and non-existence of solutions of this type and obtain information on which concentrations tend to zero when overload breakdown occurs. As a starting point we take a model of Pettersson and Ryde-Pettersson which seems to be prone to overload breakdown and a modification of it due to Poolman which was intended to avoid this effect.

Dynamical systems theoryGeneral MathematicsMolecular Networks (q-bio.MN)0206 medical engineeringZero (complex analysis)02 engineering and technologyDynamical Systems (math.DS)Photosynthesis01 natural sciencesComputer Science Applications010101 applied mathematics92C40FOS: Biological sciencesKey (cryptography)FOS: MathematicsQuantitative Biology - Molecular NetworksStatistical physics0101 mathematicsMathematics - Dynamical Systems020602 bioinformaticsMathematics
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