Wood density of European trees decreasing continuously since 1870
Aug. 14, 2018 - Trees are growing more rapidly due to climate change. This sounds like good news. After all, this means that trees are storing more carbon dioxide from the atmosphere in their wood and hence taking away the key ingredient in global warming. But is it that simple? A team from the Technical University of Munich (TUM) analyzed wood samples from the oldest existing experimental areas spanning a period of 150 years — and reached a surprising conclusion.
The team led by Hans Pretzsch, professor of forest growth and yield science at the TUM, examined wood samples from several hundred trees and analyzed every single annual ring using a high-tech procedure — a total of 30,000 of them. "The heart of the lignostation is a high-frequency probe which scans each sample in steps of a hundredth of a millimeter," says Pretzsch, explaining the analysis procedure. "By doing so, we measure the specific weight of the wood with an accuracy and resolution which until recently was unthinkable."
The wood samples come from the oldest experimental forest plots in Europe which were created at the same time the TU Munich was founded 150 years ago. The samples were taken from common European tree species such as spruces, pines, beeches, and oaks. "We have detailed knowledge of the history of every single plot and tree," says Pretzsch. "This allows us to rule out the possibility that our findings could result from the forest being managed differently now as compared to a hundred years ago."
Climate change is making the wood lighter
With the combination of wood samples from the 1870s to the present day coupled with the latest measurement technology, the team at the School of Life Sciences Weihenstephan were able to demonstrate that the annually growing wood has gradually become lighter since observations began — by up to eight to 12 per cent since 1900. Within the same period, the volume growth of the trees in central Europe has accelerated by 29 to 100 per cent.
In other words, even though a greater volume of wood is being produced today, it now contains less material than just a few decades ago. However, the explanation which immediately comes to mind does not apply. "Some people might now surmise that the more rapid growth could itself be the cause for our observations," says Dr. Peter Biber, co-author of the study. "In some tree species, it is in fact the case that wider annual rings also tend to have lighter wood. But we have taken this effect into account. The decrease in wood density we are talking about is due to other factors."
Instead, Pretzsch and his team see the causes as being the long-term increase in temperature due to climate change and the resulting lengthening of the vegetation period. But the nitrogen input from agriculture, traffic, and industry also play a part. A number of details lead experts to surmise this, such as the decrease in the density of late wood and the increase in the percentage of early wood in the annual rings.
Lighter wood — What's the problem?
Lighter wood is less solid and it has a lower calorific value. This is crucial for numerous application scenarios ranging from wood construction to energy production. Less solid wood in living trees also increases the risk of damage events such as breakage due to wind and snow in forests.
But the most important finding for practical and political aspects is that the current climate-relevant carbon sequestration of the forests is being overestimated as long as it is calculated with established but outdated wood densities. "The accelerated growth is still resulting in surplus carbon sequestration," says Pretzsch. "But scaling up for the forests of central Europe, the traditional estimate would be to high by about 10 million metric tons of carbon per year."
The research group at the Chair for Forest Growth and Yield Science at the TUM School of Life Sciences Weihenstephan led by Hans Pretzsch investigates the effect of climate change on the growth, stability, and vitality of trees. An important basis for this research are the experimental plots of the Chair, on which the dynamics of forests have been measured since 1879 to answer ecological and economic questions. In the study reported here, they contribute to measuring the human footprint in forest ecosystems.
Pretzsch, H., Biber, P., Schütze, G., Kemmerer, J. and Uhl, E.: Wood density reduced while wood volume growth accelerated in Central European forests since 1870, Forest Ecology and Management, Volume 429/2018. DOI: https://doi.org/10.1016/j.foreco.2018.07.045
Pretzsch, H., Biber, P., Uhl, E., Dahlhausen, J., Schütze, G., Perkins, D., Rötzer, T., Caldentey, J., Koike, T., van Con, T., Chavanne, A., du Toit, B., Foster, K., Lefer, B.: Climate change accelerates growth of urban trees in metropolises worldwide. Scientific Reports 7/ 2017. DOI:10.1038/s41598-017-14831-w.
Pretzsch, H., Biber, P., Schütze, G., Uhl, E., Rötzer, T.: Forest stand growth dynamics in Central Europe have accelerated since 1870. Nature Communications 5/ 2014.
Prof. Dr. Hans Pretzsch
Technical University of Munich
Chair for Forest Growth
Phone: +49 (8161) 71 - 4710
The Technical University of Munich (TUM) is one of Europe's leading research universities, with around 550 professors, 41,000 students, and 10,000 academic and non-academic staff. Its focus areas are the engineering sciences, natural sciences, life sciences and medicine, combined with economic and social sciences. TUM acts as an entrepreneurial university that promotes talents and creates value for society. In that it profits from having strong partners in science and industry. It is represented worldwide with the TUM Asia campus in Singapore as well as offices in Beijing, Brussels, Cairo, Mumbai, San Francisco, and São Paulo. Nobel Prize winners and inventors such as Rudolf Diesel, Carl von Linde, and Rudolf Mößbauer have done research at TUM. In 2006 and 2012 it won recognition as a German "Excellence University." In international rankings, TUM regularly places among the best universities in Germany.
August 14, 2018 By Technical University of Munich
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