Suitability of a Combined Stomatal Conductance and Photosynthesis Model for Calculation of Leaf-Level Ozone Fluxes

M. Op de Beeck; M. Löw; H. Verbeeck; G. Deckmyn

doi:10.1055/s-2006-924635

Plant Biology, Table of Contents

Plant Biol (Stuttg) 2007; 9(2): 331-341
DOI: 10.1055/s-2006-924635

Research Paper

Georg Thieme Verlag Stuttgart KG · New York

Suitability of a Combined Stomatal Conductance and Photosynthesis Model for Calculation of Leaf-Level Ozone Fluxes

M. Op de Beeck¹ , M. Löw² , H. Verbeeck¹ , G. Deckmyn¹

¹Research Group Plant and Vegetation Ecology, University of Antwerpen UA (CDE), Universiteitsplein 1, 2610 Wilrijk, Belgium
²Ecophysiology of Plants, Department of Ecology, TU München, Am Hochanger 13, 85354 Freising, Germany

Abstract

Currently, the most important source of uncertainty in stomatal ozone flux (FO₃ ) modelling is the stomatal conductance (g_st ) factor. Hence FO₃ model accuracy will strongly depend on the g_st model being implemented. In this study the recently developed semi-empirical g_st model of Dewar was coupled to the widely known biochemical photosynthesis (A_n ) model of Farquhar. The g_st performance of this model combination was evaluated with a 4-month time series of beech (Fagus sylvatica L.) measurements. The g_st model was hereto optimized in two steps to a 4-day and a 8-day period. A comparison between the modelled and measured g_st to O₃ (g_stO₃ ) revealed a rather good overall performance (R² = 0.77). Errors between the model combination and the measurements are thought to be largely caused by a moderate performance of the A_n model, due to poor parameterization. Two 2-day periods with distinctly differing soil and meteorological conditions were chosen to give a picture of the daily g_st performance. Although instant relative differences between modelled and measured g_stO₃ are sometimes high, the model combination is able to simulate the rough daily courses of g_stO₃ and hence FO₃ reasonably well. Further improvement on full parameterization of the g_st model and a well-parameterized A_n model to be linked to are needed to draw founded conclusions about its performance. Future efforts hereto are certainly justified since the model's mechanistic nature makes it a tool able to model g_st variation in space and time, O₃ effects on g_st, and effective FO₃ .

Key words

Beech - Fagus sylvatica L. - model - stomatal conductance - ozone flux.

Full Text

References

21 Bayerische Staatsforstverwaltung .Auswirkungen der Trockenheit 2003 - Waldschutzsituation 2004. München; LWF (2004): 44
1 Brasseur G. P., Müller J.-F., Tie X., Horowitz L.. Tropospheric ozone and climate: past, present and future. Matsuno, T. and Kida, H., eds. Present and Future of Modeling Global Environmental Change: Toward Integrated Modeling. Tokyo; Terrapub (2001): 63-75
2 Campbell G. S., Norman J. M.. An Introduction to Environmental Biophysics. 2nd ed. New York; Springer-Verlag (1998): 289pp
26 Deckmyn G., Op de Beeck M., Löw M., Then C., Verbeeck H., Wipfler P., Ceulemans R.. Modelling ozone effects on adult beech trees through simulation of defence, damage, and repair costs: implementation of the CASIROZ ozone model in the ANAFORE forest model. Plant Biology. (2007); 9 320-330
3 de Pury D. G. G., Farquhar G. D.. Simple scaling of photosynthesis from leaves to canopies without the errors of big-leaf models. Plant, Cell and Environment. (1997); 20 537-557
4 Dewar R. C.. The Ball-Berry-Leuning and Tardieu-Davies stomatal models: synthesis and extension within a spatially aggregated picture of guard cell function. Plant, Cell and Environment. (2002); 25 1383-1398
5 Emberson L. D., Ashmore M. R., Cambridge H. M., Simpson D., Tuovinen J.-P.. Modelling stomatal flux across Europe. Environmental Pollution. (2000); 109 403-413
6 Farquhar G. D., von Caemmerer S., Berry J. A.. A biochemical model of photosynthetic CO₂ assimilation in leaves of C₃ species. Planta. (1980); 149 78-90
7 Hough A. M., Derwent R. G.. Changes in the global concentration of tropospheric ozone due to human activities. Nature. (1990); 344 645-648
8 Jones H. G.. Plants and Microclimate. A Quantitative Approach to Environmental Plant Physiology. 2nd ed. Cambridge; University Press (1992): 428pp
9 Jones H. G., Sutherland R. A.. Stomatal control of xylem embolism. Plant, Cell and Environment. (1991); 14 607-612
10 Lemoine D., Jacquemin S., Granier A.. Beech (Fagus sylvatica L.) branches show acclimation of xylem anatomy and hydraulic properties to increased light after thinning. Annals of Forest Science. (2002); 59 761-766
11 Leuning R., Tuzet A., Perrier A.. Stomata as part of the soil-plant-atmosphere continuum. Menchuccini, M., Grace, J., Moncrieff, J., and McNaughton, K. G., eds. Forests at the Land-Atmosphere Interface. Wallingford; CABI Publishing (2004): 9-28
12 Leuschner C., Hertel D., Schmid I., Koch O., Muhs A., Holscher D.. Stand fine root biomass and fine root morphology in old-growth beech forests as a function of precipitation and soil fertility. Plant and Soil. (2004); 258 43-56
13 Lindskog A., Beekmann M., Monks P., Roemer M., Schuepbach E., Solberg S.. Tropospheric ozone research, overview of subproject TOR‐2. Midgley, P. M. and Reuther, M., eds. Towards Cleaner Air for Europe - Science, Tools and Applications, Part 2. Overviews from the Final Reports of the EUROTRAC‐2 Subprojects. Weikersheim; Margraf Verlag (2003): 251-270
14 Matyssek R., Sandermann H.. Impact of ozone on trees: an ecophysiological perspective. Progress in Botany. Heidelberg; Springer-Verlag (2003): 349-404
27 Matyssek R., Bahnweg G., Ceulemans R., Fabian P., Grill D., Hanke D. E., Kraigher H., Oßwald W., Rennenberg H., Sandermann H., Tausz M., Wieser G.. Synopsis of the CASIROZ case study: carbon sink strength of Fagus sylvatica L. in a changing environment - experimental risk assessment of mitigation by chronic ozone impact. Plant Biology. (2007); 9 163-180
15 Mills (ed.) G.. Mapping critical levels for vegetation. Manual on methodologies and criteria for modelling and mapping critical loads and levels and air pollution effects, risks and trends, Chapter 3. UNECE Convention on Longe-Range Transboundary Air Pollution. (2004): 52pp
16 Monteith J. L., Unsworth M. H.. Principles of Environmental Physics. London; Edward Arnold (1990): 291pp
17 Newman E. I.. Resistance to water flow in soil and plant. I. Soil resistance in relation to amounts of root: theoretical estimates. Journal of Applied Ecology,. (1969); 6 1-12
18 Nunn A. J., Kosovitz A. R., Reiter I. M., Heerdt C., Leuchner M., Lütz C., Liu X., Winkler J. B., Grams T. E. E., Häberle K.-H., Werner H., Fabian P., Rennenberg H., Matyssek R.. Comparison of ozone uptake and sensitivity between a phytotron study with young beech and a field experiment with adult beech (Fagus sylvatica). Environmental Pollution. (2005); 137 494-506
19 Penman H. L.. Natural evaporation from open water, bare soil and grass. Proceedings of the Royal Society, London Series A. (1948); 193 120-145
20 Pell E. J., Schlagnhaufer C. D., Arteca R. N.. Ozone-induced oxidative stress: mechanisms of action and reaction. Physiologia Plantarum. (1997); 100 264-273
22 Stone E. L., Kalisz P. J.. On the maximum extent of roots. Forest Ecology and Management. (1991); 46 59-102
23 Torsethaugen G., Pell E. J., Assmann S.. Ozone inhibits guard cell K+ channels implicated in stomatal opening. Tree Physiology. (1999); 96 13577-13582
24 Tuovinen J. P., Ashmore M. R., Emberson L. D., Simpson D.. Testing and improving the EMEP ozone deposition module. Atmospheric Environment. (2004); 38 2373-2386
25 Werner H., Fabian P.. Free-air fumigation of mature trees. Environmental Science and Pollution Research. (2002); 9 117-121

M. Op de Beeck

Research Group Plant and Vegetation Ecology
University of Antwerpen, CDE

Universiteitsplein 1

2610 Wilrijk/Antwerpen

Belgium

Email: maarten.opdebeeck@ua.ac.be

Guest Editor: R. Matyssek