Measuring and modelling carbon dioxide and water vapour exchange over a temperate broad‐leaved forest during the 1995 summer drought

Baldocchi, Dennis

doi:10.1046/j.1365-3040.1997.d01-147.x

Cited by 288 publications

(264 citation statements)

References 78 publications

(52 reference statements)

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“…The heat stored by net carbon assimilation is illustrated in figure 2e, and corresponds well with values found by other authors [3,4]. A clear diurnal course was observed.…”

Section: Diurnal Behaviour Of Storage Componentssupporting

confidence: 90%

Energy balance storage terms and big-leaf evapotranspiration in a mixed deciduous forest

Samson

Lemeur²

2001

Ann. For. Sci.

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-Five different heat storage terms were studied in a mixed deciduous forest. All terms should be taken into account for the calculation of the overall heat storage, because they all can be significant during certain weather conditions and hours. Heat storage in biomass is estimated using surface temperatures measured with an infrared radiometer, which seems to be a good method. The often neglected photosynthetic heat storage may not be omitted. On a seasonal basis soil heat storage seems to be the most important term. The overall heat storage shows a small tendency for releasing heat to the atmosphere during fall. Fluctuations in overall heat storage are a result of complex changes of several climatic parameters. Due to the high degree of coupling of the forest to the atmosphere, accurate measurements of overall heat storage for the determination of big leaf forest evapotranspiration are not of the utmost importance. energy storage / deciduous forest / evapotranspiration / infrared radiometer / coupling Résumé -Détermination des termes du bilan d'énergie et calcul de l'évapotranspiration par un modèle « big-leaf » en peuplement feuillu mélangé. Cinq termes différents du bilan d'énergie ont été étudiés dans un peuplement feuillu mélangé. Etant donné que chacun de ces termes peut être significatif en fonction de l'heure et des conditions climatiques, ils doivent tous être pris en compte pour un calcul précis. L'énergie stockée dans la biomasse a été estimée à partir de la température de surface, mesurée à l'aide d'un radiomètre infrarouge. La méthode donne de bons résultats. Le stock d'énergie photosynthétique est non négligeable quoique souvent omis. Sur une base saisonnière, le stock d'énergie dans le sol est le terme le plus important. Lors de la chute des feuilles, on observe un flux positif d'énergie de l'écosystème vers l'atmosphère. Les variations du stock total d'énergie dans l'écosystème sont sous le contrôle d'un ensemble complexe de plusieurs paramètres climatiques. Cependant, étant donné le degré de couplage élevé entre la forêt et l'atmosphère, la mesure précise du stock total d'énergie dans l'écosystème n'est pas des plus importants pour le calcul de l'évapotranspiration par un modèle « big-leaf ». stockage d'énergie / forêt feuillue / évapotranspiration / radiomètre infrarouge / couplage

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“…The heat stored by net carbon assimilation is illustrated in figure 2e, and corresponds well with values found by other authors [3,4]. A clear diurnal course was observed.…”

Section: Diurnal Behaviour Of Storage Componentssupporting

confidence: 90%

Energy balance storage terms and big-leaf evapotranspiration in a mixed deciduous forest

Samson

Lemeur²

2001

Ann. For. Sci.

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“…Although actual leaf growth, C and N translocation, and plant water relations represented by these leaf characteristics change continuously in response to changing internal and external conditions [Tanaka et al, 2002], micrometeorological data used to estimate these parameters are also subject to mea- surement errors. Some authors have addressed this measurement uncertainty by estimating ecosystem properties (i.e., light response curves, respiration rates) from flux measurements averaged across several days [Baldocchi, 1997]. Instead of averaging the flux measurements, we fitted single values of the parameters across a period of several days.…”

Section: Seasonal Patterns Of Ecosystem Parametersmentioning

confidence: 99%

Inverse estimation of Vc_max, leaf area index, and the Ball‐Berry parameter from carbon and energy fluxes

Wolf

Akshalov

Saliendra³

et al. 2006

J. Geophys. Res.

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[1] Canopy fluxes of CO 2 and energy can be modeled with high fidelity using a small number of environmental variables and ecosystem parameters. Although these ecosystem parameters are critically important for modeling canopy fluxes, they typically are not measured with the same intensity as ecosystem fluxes. We developed an algorithm to estimate leaf area index (LAI), maximum carboxylation velocity (Vc max ), the Ball-Berry parameter (m), and substrate-dependent ecosystem respiration rate (b A ) by inverting a commonly used modeling paradigm of canopy CO 2 and energy fluxes. To test this algorithm, fluxes of sensible heat (H), latent heat (LE), and CO 2 (Fc) were measured with eddy covariance techniques in a pristine grassland-forb steppe site in northern Kazakhstan. We applied the algorithm to these data and identified ecosystem characteristics consistent with data across a time series of meteorological drivers from the Kazakhstan data. LAI was calculated by fitting the model to measured H + LE, Vc max and b A were solved simultaneously by fitting the model to measured CO 2 fluxes, and m was calculated by varying the partitioning of available energy between H and LE. Seasonal changes in LAI ranged from 2.0 to 2.4, Vc max declined from 20 to 5 mmol CO 2 m À2 s À1 , respiration as a percentage of assimilation ranged from 0.5 to 0.75, and m varied from 17 to 24. Our results with the Kazakhstan data showed that LAI, Vc max , ecosystem respiration, and m can be solved to accurately predict (R 2 = 80 to 95%) carbon and energy fluxes with nonsignificant bias at 20-min and daily timescales. The ecosystem characteristics calculated in our study were consistent with independent measurements of the seasonal dynamics of a shortgrass steppe in Kazakhstan and with values published in the literature. These characteristics were closely linked to mean daily fluxes of CO 2 but were not dependent on the environmental drivers for the periods they were measured. We conclude that process model inversion has potential for comparing CO 2 and energy fluxes among different ecosystems and years and for providing important ecosystem parameters for evaluating climatic influences on CO 2 and energy fluxes.

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“…EC fluxes were calculated as F = p<w'C'>, where F represents flux of sensible heat, latent heat, or CO2, p is air density, w is vertical wind velocity, C is CO2 mixing ratio (or temperature or water vapor), <> represents Reynolds averaging, and the primes represent deviation from the Reynolds average [e.g., Baldocchi et al, 1988]. Mean CO2 mixing ratios were measured at 36, 18, 10, and 0.75 m to compute canopy CO2 storage as described by Baldocchi [1997]. Eddy covariance and storage fluxes are reported as 30-min averages.…”

Section: Eddy Covariance and Canopy Storage Fluxesmentioning

confidence: 99%

Dynamics of isotopic exchange of carbon dioxide in a Tennessee deciduous forest

Bowling

Baldocchi

Monson

1999

Global Biogeochemical Cycles

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Abstract. The combination of isotopic measurements and micrometeorological flux measurements is a powerful new approach that will likely lead to new insight into the dynamics of CO2 exchange between terrestrial ecosystems and the atmosphere. Since the biological processes of photosynthesis and respiration modify the stable isotopic signature of atmospheric CO2 in different ways, measurements of the net fluxes of CO2, 13CO2, and C18OO can be used to investigate the relative contribution of each process to net ecosystem CO2exchange. We used two independent approaches to measure isotopic fluxes of CO2over a Tennessee oak-maple-hickory forest in summer 1998. These approaches involved (1) a combination of standard eddy covariance with intensive flask sampling, and (2) a modification to the relaxed eddy accumulation technique. Strong isotopic signals associated with photosynthesis and respiration were observed and persisted in forest air despite the potential for mixing due to atmospheric turbulence. Calm nights allowed a buildup of respiratory CO2below the canopy and were associated with isotopically depleted forest air in the morning. Windy nights were followed by a relatively more enriched early-morning isotopic signal. Entrainment of air from above the decaying nocturnal boundary layer during daytime mixed layer growth exerted strong control on isotopic composition of forest air, resulting in similar isotope ratios in the late afternoon despite different isotopic starting points following calm or windy nights. The influences of the convective boundary layer and turbulent mixing within the forest cannot be ignored when using isotopes of CO2to investigate biological processes.

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Measuring and modelling carbon dioxide and water vapour exchange over a temperate broad‐leaved forest during the 1995 summer drought

Cited by 288 publications

References 78 publications

Energy balance storage terms and big-leaf evapotranspiration in a mixed deciduous forest

Energy balance storage terms and big-leaf evapotranspiration in a mixed deciduous forest

Inverse estimation of Vc_max, leaf area index, and the Ball‐Berry parameter from carbon and energy fluxes

Dynamics of isotopic exchange of carbon dioxide in a Tennessee deciduous forest

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Measuring and modelling carbon dioxide and water vapour exchange over a temperate broad‐leaved forest during the 1995 summer drought

Cited by 288 publications

References 78 publications

Energy balance storage terms and big-leaf evapotranspiration in a mixed deciduous forest

Energy balance storage terms and big-leaf evapotranspiration in a mixed deciduous forest

Inverse estimation of Vcmax, leaf area index, and the Ball‐Berry parameter from carbon and energy fluxes

Dynamics of isotopic exchange of carbon dioxide in a Tennessee deciduous forest

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Inverse estimation of Vc_max, leaf area index, and the Ball‐Berry parameter from carbon and energy fluxes