Assessing forest productivity in Australia and New Zealand using a physiologically-based model driven with averaged monthly weather data and satellite-derived estimates of canopy photosynthetic capacity

To evaluate the effects of spatial variation in climate and soils on forest productivity across broad regions requires an approach that can be widely applied and tested. Detailed physiological and micro-meteorological studies have recently lead to new insights that greatly simplify the prediction of...

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Bibliographic Details
Published in:Forest ecology and management 1998-05, Vol.104 (1), p.113-127
Main Authors: Coops, N.C, Waring, R.H, Landsberg, J.J
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
AUSTRALIA
AUSTRALIE
AVHRR
Biological and medical sciences
CANOPY
CLIMA
CLIMAT
CLIMATE
COUVERT
CUBIERTA DE COPAS
Dendrometry. Forest inventory
Ecosystem remote sensing
Eucalypt forest
EUCALYPTUS
Forestry
FOTOSINTESIS
Fraction of photosynthetic active radiation ( fPAR)
Fundamental and applied biological sciences. Psychology
MODELE
MODELOS
Net primary productivity (NPP)
NEW ZEALAND
NOUVELLE ZELANDE
NUEVA ZELANDIA
PHOTOSYNTHESE
PHOTOSYNTHESIS
PRODUCCION DE MADERA
PRODUCTION DU BOIS
PRODUCTIVIDAD
PRODUCTIVITE
PRODUCTIVITY
Synecology
TEMPS METEOROLOGIQUE
Terrestrial ecosystems
TIEMPO METEOROLOGICO
WEATHER
WOOD PRODUCTION
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Summary:To evaluate the effects of spatial variation in climate and soils on forest productivity across broad regions requires an approach that can be widely applied and tested. Detailed physiological and micro-meteorological studies have recently lead to new insights that greatly simplify the prediction of above-ground net primary production (NPP), a variable closely related to conventional measures of forest growth, such as Mean Annual Increment (MAI) of stemwood. We applied these simplifications in a monthly time-step model driven by estimates of the fraction of light intercepted by green canopies, derived from near-infrared and red reflectances monitored from National Oceanographic and Atmospheric Administration (NOAA) weather satellites, and from equations utilising local temperature and rainfall records. Absorbed photosynthetically active radiation (APAR) was estimated from global solar radiation, derived from an established empirical relationship based on average maximum and minimum temperatures, and from a linear relation with the satellite-derived normalised difference vegetation index (NDVI) which represents the photosynthetic capacity of all vegetation within a cell for a given month and is often correlated with the fraction of PAR absorbed ( fPAR). Monthly values of environmental constraints on productivity were expressed by modifiers calculated from the vapour pressure deficit (VPD) of the atmosphere, soil water deficit, or frost. This procedure leads to estimates of utilisable radiation (APARu). Gross primary production (GPP) was calculated by multiplying APARu by a constant canopy quantum efficiency (1.8 g C MJ −1) and total NPP has been shown, in a number of studies, to approximate 0.45±0.05 of GPP. The model partitions NPP into root and above-ground foliage and stem mass. The fraction of total NPP allocated to root growth increases from 0.2 to 0.6 as the ratio APARu:APAR decreases from 1.0 to 0.2. Above ground NPP (NPP A) predicted by the model was compared with estimated above-ground NPP derived at eight contrasting forested sites in Australia and New Zealand. There was a linear relation between predicted NPP A and measured wood production ( r 2=0.82). The analysis also provided an assessment of the relative importance of various climatic variables upon production which varied extensively from site to site.
ISSN:0378-1127
1872-7042
DOI:10.1016/S0378-1127(97)00248-X