Bruno Lasserre

Investigating biochemical processes to assess deadwood decay of beech and silver fir in Mediterranean mountain forests

ContextWe investigated the relationships between decay classes, morphological characteristics and chemical compounds in Abies alba Mill. and Fagus sylvatica L. stumps in two forest stands in the central Apennines (Italy). The analysis of deadwood decomposition is important in estimating carbon sequestration potential and carbon residence time in forest ecosystems. In addition, deadwood decomposition affects nutrient cycling and microhabitat distribution.AimsThe overall aim of this study was to investigate the decomposition processes in a mountainous Mediterranean ecosystem, and specifically to assess changes in chemical variables (lignin, cellulose, carbon and nitrogen content) in deadwood during the decomposition process, in relation to decay classes and to the species.MethodsCross-sections were collected from stumps. Samples were assigned to visually discernible decay classes, and cellulose, lignin and carbon (C) and nitrogen (N) content in relation to total dry mass were analysed during the decay process.ResultsResults showed how C/N ratio decreased over decades due to an increase in nitrogen content. On the contrary, carbon concentration in stumps remained substantially stable. Lignin degraded slowly in comparison with cellulose and differences between species were observed.ConclusionThe hypothesis that the conifer species would decompose faster than deciduous species did not prove correct. The slower decay of lignin compared to cellulose suggested that lignin could be an important long-term source of soil organic carbon, and that this process could be greatly affected by forest species mixtures. Finally, decomposition processes in the investigated montane–Mediterranean forests were definitely faster than in the colder climates of northern Europe.

Involvement of lignin and hormones in the response of woody poplar taproots to mechanical stress

Mechanical stress is a widespread condition caused by numerous environmental factors that severely affect plant stability. In response to mechanical stress, plants have evolved complex response pathways able to detect mechanical perturbations and inducing a suite of modifications in order to improve anchorage. The response of woody roots to mechanical stresses has been studied mainly at the morphological and biomechanical level, whereas investigations on the factors triggering these important alterations are still at the initial stage. Populus has been widely used to study the response of stem to different mechanical stresses and, since it has the first forest tree genome to be decoded, represents a model woody plant for addressing questions on the mechanisms controlling adaptation of woody roots to changing environments. In this study, a morphological and physiological analysis was used to investigate factors controlling modifications in Populus nigra woody taproots subjected to mechanical stress. An experimental model analyzing spatial and temporal mechanical force distribution along the woody taproot axis enabled us to compare the events occurring in its above-, central- and below-bending sectors. Different morphogenetic responses and local variations of lignin and plant hormones content have been observed, and a relation with the distribution of the mechanical forces along the stressed woody taproots is hypothesized. We investigated the differences of the response to mechanical stress induction during the time; in this regard, we present data referring to the effect of mechanical stress on plant transition from its condition of winter dormancy to that of full vegetative activity.

Long tree-ring chronologies provide evidence of recent tree growth decrease in a Central African tropical forest.

It is still unclear whether the exponential rise of atmospheric CO2 concentration has produced a fertilization effect on tropical forests, thus incrementing their growth rate, in the last two centuries. As many factors affect tree growth patterns, short -term studies might be influenced by the confounding effect of several interacting environmental variables on plant growth. Long-term analyses of tree growth can elucidate long-term trends of plant growth response to dominant drivers. The study of annual rings, applied to long tree-ring chronologies in tropical forest trees enables such analysis. Long-term tree-ring chronologies of three widespread African species were measured in Central Africa to analyze the growth of trees over the last two centuries. Growth trends were correlated to changes in global atmospheric CO2 concentration and local variations in the main climatic drivers, temperature and rainfall. Our results provided no evidence for a fertilization effect of CO2 on tree growth. On the contrary, an overall growth decline was observed for all three species in the last century, which appears to be significantly correlated to the increase in local temperature. These findings provide additional support to the global observations of a slowing down of C sequestration in the trunks of forest trees in recent decades. Data indicate that the CO2 increase alone has not been sufficient to obtain a tree growth increase in tropical trees. The effect of other changing environmental factors, like temperature, may have overridden the fertilization effect of CO2.

Patterns and trends in tropical forest cover

Abstract In the 2005 edition of the Global Forest Resources Assessment of the Food and Agriculture Organization of the United Nations, a moderate negative trend was reported regarding the change of tropical forests: the net annual change was estimated at −11.8 million ha for the period 2000–2005, while the rate was −11.65 for the previous decade. Tropical Asia showed the highest rate and most negative trend, passing from −0.8% to −0.96% per year. The remote sensing survey done for previous Forest Resource Assessment editions covering the period 1980–2000 revealed distinct change processes in the three tropical regions. Survey results indicated that socio‐economic and cultural aspects that characterise and differentiate the geographic regions determine the nature of the change processes and underlying cause–effect mechanisms, while the ecological setting determines the intensity of change and reveals its environmental implications. A comparison of deforestation processes of the two decades indicated an on‐going process of “radicalisation” of the dynamics determined by an increasing frequency of high‐gradient changes (e.g. total clearing rather than fragmentation and degradation) and by a shift of deforestation fronts towards wetter zones, with a consequent higher per‐hectare carbon emission associated with deforested areas.

Dynamics of the silver fir (Abies alba Mill.) natural regeneration in a mixed forest in the Central Apennine

Abstract The dynamics of the silver fir represent an important topic for researchers across Europe. Following its decline, which occurred in Europe after the last glaciation, the remaining relict areas became a very important laboratory for studying its conservation. The Central Apennine chain, particularly in Molise, represents one unique case where silver fir, Turkey oak and beech can be found within the same forest. This study focused on the forest structure of the Bosco Monteluponi where the closeness with Collemeluccio Man and Biosphere reserve has affected the diffusion of conifer within the forest. Consequently, the forest structure has shifted from even aged to uneven aged. The resulting complex forest structure offers new challenges for forest practitioners in the identification of silvicultural treatments, which identify and maintain the balance among the three species within the same forest. Particular importance was given to the silver fir natural regeneration in order to assess the forest suitability for conifer expansion. Results demonstrated that Monteluponi is strongly suitable for the in situ conservation of silver fir and offers a great opportunity for its diffusion.

First mapping of the main high conservation value forests (HCVFs) at national scale: The case of Italy

Abstract Forest certification is one of the many tools that have been developed to achieve sustainable forest management. The Forest Stewardship Council (FSC) was the first organization to develop an independent forest certification scheme in early 1990s. FSC standards introduced the concept of high conservation value forests (HCVFs) that identifies forest areas with high conservation values (HCVs) according to six different categories including environmental services, social and cultural values, rare, threatened or endangered species, and ecosystems and habitats. HCVFs are becoming more relevant even beyond forest certification purposes, and the concept is increasingly being adopted and used as a tool for improving forest management operations. This paper represents a preliminary study for the identification and mapping of the main HCVFs in Italy. It is based on existing information and available datasets and identifies some out of six existing HCVs categories. The extent of forest areas identified as HCVFs in Italy varies according to the HCV category taken into consideration. Altogether, the HCVs investigated correspond to about 66% of the Italian forest. This preliminary study on HCVFs in Italy and GIS tools had proved to be a useful support for the identification and analysis of investigated areas for the purposes of both facilitating certification processes and improved management of national forests.

Biomass Growth Rate of Trees from Cameroon Based on 14C Analysis and Growth Models

The question of whether the rise in CO2 levels observed during the industrial era has influenced the rates of tree biomass growth represents one of the main unsolved questions in the field of climate change science. In this framework, the African tropical forest represents one of the most important carbon (C) sinks, but detailed knowledge of its response to elevated CO2 is still lacking, especially regarding tree growth rate estimations. A major limitation to determining growth rates in the African tropical region is that many trees lack seasonality in cambial activity determining annual growth rings. In this study, several species of trees characterizing the African tropical forest have been investigated to estimate their biomass growth rate by means of a procedure based on 14C and growth models. A total of 71 subsamples were analyzed for a Entandrophragma cylindricum (sapele) tree, and 38 and 25 wood subsamples for Erythrophleum suaveolens (tali) and Triplochiton scleroxylon (ayous) trees, respectively, using radiocarbon measurements at the Centre for Isotopic Research on Cultural and Environmental Heritage (CIRCE). All measured modern samples were in agreement with the Southern Hemisphere (SH) 14C bomb-spike curve. Observed preliminary results indicate a decrease in the growth rate of the sapele tree (~350 yr old) in the industrial period compared to the pre-industrial era. Growth rates for trees of the other 2 species were higher than sapele, with ayous being the fastest-growing species. DOI:xa0 10.2458/azu_js_rc.55.16243

EFO-LCI: A New Life Cycle Inventory Database of Forestry Operations in Europe

Life cycle assessment (LCA) has become a common methodology to analyze environmental impacts of forestry systems. Although LCA has been widely applied to forestry since the 90s, the LCAs are still often based on generic Life Cycle Inventory (LCI). With the purpose of improving LCA practices in the forestry sector, we developed a European Life Cycle Inventory of Forestry Operations (EFO-LCI) and analyzed the available information to check if within the European forestry sector national differences really exist. We classified the European forests on the basis of “Forest Units” (combinations of tree species and silvicultural practices). For each Forest Unit, we constructed the LCI of their forest management practices on the basis of a questionnaire filled out by national silvicultural experts. We analyzed the data reported to evaluate how they vary over Europe and how they affect LCA results and made freely available the inventory data collected for future use. The study shows important variability in rotation length, type of regeneration, amount and assortments of wood products harvested, and machinery used due to the differences in management practices. The existing variability on these activities sensibly affect LCA results of forestry practices and raw wood production. Although it is practically unfeasible to collect site-specific data for all the LCAs involving forest-based products, the use of less generic LCI data of forestry practice is desirable to improve the reliability of the studies. With the release of EFO-LCI we made a step toward the construction of regionalized LCI for the European forestry sector.

A simple multivariate analysis to assess diversity in a complex long-term managed forest area in central Italy

Today wood and nonwood forest resources management meets and often clashes with environment and biological diversity protection. A main problem is to understand relationships between the different roles of forest biodiversity, site, and management parameters. A multivariate statistical analysis has been carried out in order to interpret relationships between some forest biodiversity components and forest inventory data. Several indices of floristic diversity, species abundance, and structural heterogeneity at stand level have been calculated. The different components of forest biodiversity were separated by principal components analysis. Relations between forest biodiversity indices and site and management attributes have been investigated by two multivariate statistical techniques: bivariate correlation analysis and multiple linear regression. Results showed a high correlation between all the investigated components of forest biodiversity and some topographic and/or forest management attributes. Results also gave ancillary information to define sustainable forest management criteria.

Carbon Losses Due to Wood Harvesting and the Role of Wood Products

The carbon stock in wood and paper products is increasing in Italy, and the same trend is expected in the coming decades. In forest ecosystems firewood and forest harvesting represent a net carbon loss but the use of wood, a carbon-neutral renewable resource for generating energy also has a strong substitution effect as it avoids the use of fossil fuels which are highly CO2 emitting. The use of wood for construction purposes, substituting traditional materials, tends to increase carbon sequestration and contributes to climate change mitigation. The application of the GHGs accounting methods (IPCC 2003) suffers in Italy both for the lack of accuracy of wood harvesting official statistics and for the high level of uncertainty in the definition of wood products lifespan. Many authors have demonstrated a large underestimation of clear cuts areas in Italy leading to an underestimation of carbon loss due to a harvesting of about 2 Mt annually. However, it has been recently proved that multitemporal high resolution remotely sensed images may be operatively used with a probabilistic sampling procedure to obtain a more reliable estimation of annual wood harvesting extents. In any case an increase of the use of wood products for energy, building and furniture purposes may contribute to the reduction of GHG emissions and to a more sustainable development.