Anna Jönsson scite author profile

Two models for predicting the hydration status of lichens were developed as a first step towards a mechanistic lichen productivity model. A biophysical model included the water potential of the air, derived from measurements of air temperature, relative humidity and species-specific rate constants for desiccation and rehydration. A reduced physical model, included only environmental parameters, assuming instantaneous equilibration between the lichen and the air. These models were developed using field and laboratory data for three green algal lichens: the foliose epiphytic Platismatia glauca (L.) W. Culb., the fruticose epiphytic Alectoria sarmentosa (Ach.) Ach. and the fruticose, terricolous and mat-forming Cladina rangiferina (L.) Weber ex Wigg. The models were compared and validated for the same three species using data from a habitat with a different microclimate. Both models predicted the length and timing of lichen hydration periods, with those for A. sarmentosa and P. glauca being highly accurate-nearly 100% of the total wet time was predicted by both the biophysical and physical models. These models also predicted an accurate timing of the total realized wet time for A. sarmentosa and P. glauca when the lichens were wet. The model accuracy was lower for C. rangiferina compared to the epiphytes, both for the total realized wet time and for the accuracy of the timing for the hydration period. These results demonstrate that the stochastic and continually varying hydration status of lichens can be simulated from biophysical data. Further development of these models to also include water-related activity, light and temperature conditions during the hydration events will then be a potent tool to assess potential lichen productivity in landscapes and habitats of various microclimatic conditions.

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New Exponent for the NonlinearIVCharacteristics of a Two Dimensional Superconductor

Minnhagen

Westman

Jönsson

et al. 1995

Phys. Rev. Lett.

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Characteristics of two-dimensional vortex dynamics from XY-type models with Ginzburg-Landau dynamics

Jönsson

Minnhagen

1997

Phys. Rev. B

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A method based on the chi-square test for document classification

Oakes

Gaaizauskas

Fowkes

et al. 2001

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Flux noise and vortex dissipation for two-dimensional superconductors

1994

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A relation is presented which relates the Sux noise spectrum and vortex dissipation for twodimensional superconductors. The explicit forms of the noise spectrum and vortex dissipation are obtained from simulations of a two-dimensional XY-type model with time-dependent Ginzburg-Landau dynamics. The results are discussed in terms of a phenomenological description and good agreement is found. Consequences for, and comparisons with, experimental data are discussed.

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Anna Jönsson

Predicting lichen hydration using biophysical models

New Exponent for the NonlinearIVCharacteristics of a Two Dimensional Superconductor

Characteristics of two-dimensional vortex dynamics from XY-type models with Ginzburg-Landau dynamics

A method based on the chi-square test for document classification

Flux noise and vortex dissipation for two-dimensional superconductors

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