Abstract

Quantification of forest Gross Primary Productivity (GPP) is important for understanding ecosystem function and designing appropriate carbon mitigation strategies. Coupling forest biometric data with canopy photosynthesis models can provide a means to simulate GPP across different stand ages. In this study we developed a simple framework to integrate biometric and leaf gas-exchange measurements, and to estimate GPP across four Mediterranean pine forests of different post-fire age. We used three different methods to estimate the Leaf Area Index (LAI) of the stands, and monthly gas exchange data to calibrate the photosynthetic light response of the leaves. Upscaling of carbon sequestration at the canopy level was made by implementing a Big Leaf and a Sun/Shade model, using both average and variant (monthly) photosynthetic capacity values. The Big Leaf model simulations systematically underestimated GPP compared to the Sun/Shade model simulations. Our simulations suggest an increasing GPP with age up to a stand maturity stage. The shape of the GPP trend with stand age was not affected by the method used to parameterise the model. At the scale of our study, variability in stand and canopy structure among the study sites seems to be the key determinant of GPP.

Highlights

  • The Litterfall Method (LFM) estimated higher values for Leaf Area Index (LAI) compared to hemispherical photography method (HPM) and ceptometer method (CMM)

  • The Big Leaf model setups systematically underestimated Gross Primary Productivity (GPP) compared to the Sun/Shade model setups

  • In this study we presented a simplified framework to estimate GPP in Mediterranean pine forests of different post-fire age

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Summary

Introduction

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Forest ecosystems are vital for the survival of human kind as they provide material, economical and recreational resources [1], as well as fresh water, soil protection and other ecosystem services [2]. Many scholars focus on the role of carbon (C) cycling within forests, and the way this process is affected by global change [3] and interacts with the climate system [4]. To understand C dynamics, estimation of the rate of C sequestration and C stock change in forest ecosystems is crucial for ecological and global change research and policy

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