Old-Growth Trees More Drought Tolerant than Younger Ones,
Providing a Buffer Against Climate Change
A new analysis of more than 20,000
trees on five continents shows that old-growth trees are more drought tolerant
than younger trees in the forest canopy and may be better able to withstand
future climate extremes. The findings highlight the importance of preserving
the world's remaining old-growth forests, which are biodiversity strongholds
that store vast amounts of planet-warming carbon, according to forest
ecologists.
From: University
of Michigan
December 1, 2022 -- The findings highlight the
importance of preserving the world's remaining old-growth forests, which are
biodiversity strongholds that store vast amounts of planet-warming carbon,
according to University of Michigan forest ecologist Tsun Fung (Tom) Au, a postdoctoral
fellow at the Institute for Global Change Biology.
"The number of
old-growth forests on the planet is declining, while drought is predicted to be
more frequent and more intense in the future," said Au, lead author of the
study published online Dec. 1 in the journal Nature Climate Change.
"Given their high
resistance to drought and their exceptional carbon storage capacity,
conservation of older trees in the upper canopy should be the top priority from
a climate mitigation perspective."
The researchers also
found that younger trees in the upper canopy -- if they manage to survive
drought -- showed greater resilience, defined as the ability to return to
pre-drought growth rates.
While deforestation,
selective logging and other threats have led to the global decline of
old-growth forests, subsequent reforestation -- either through natural
succession or through tree planting -- has led to forests dominated by
increasingly younger trees.
For example, the area
covered by younger trees (<140 years old) in the upper canopy layer of
temperate forests worldwide already far exceeds the area covered by older
trees. As forest demographics continue to shift, younger trees are expected to
play an increasingly important role in carbon sequestration and ecosystem
functioning.
"Our findings --
that older trees in the upper canopy are more drought tolerant, while younger
trees in the upper canopy are more drought resilient -- have important
implications for future carbon storage in forests," Au said.
"These results
imply that in the short term, drought's impact on forests may be severe due to
the prevalence of younger trees and their greater sensitivity to drought. But
in the long run, those younger trees have a greater ability to recover from
drought, which could be beneficial to the carbon stock."
Those implications will
require further study, according to Au and colleagues, given that reforestation
has been identified by the Intergovernmental Panel on Climate Change as a
potential nature-based solution to help mitigate climate change.
The Sharm el-Sheikh
Implementation Plan published during the 2022 United Nations Climate Change
Conference in Egypt (COP27) also reaffirmed the importance of maintaining
intact forest cover and associated carbon storage as a social and environmental
safeguard.
"These findings
have implications for how we manage our forests. Historically, we have managed
forests to promote tree species that have the best wood quality," said
Indiana University's Justin Maxwell, a senior author of the study.
"Our findings
suggest that managing forests for their ability to store carbon and to be
resilient to drought could be an important tool in responding to climate
change, and thinking about the age of the forest is an important aspect of how
the forest will respond to drought."
The researchers used
long-term tree-ring data from the International Tree-Ring Data Bank to analyze
the growth response of 21,964 trees from 119 drought-sensitive species, during
and after droughts of the past century.
They focused on trees
in the uppermost canopy. The forest canopy is a multilayered, structurally
complex and ecologically important zone formed by mature, overlapping tree
crowns.
The upper canopy trees
were separated into three age groups -- young, intermediate and old -- and the
researchers examined how age influenced drought response for different species
of hardwoods and conifers.
They found that young
hardwoods in the upper canopy experienced a 28% growth reduction during
drought, compared to a 21% growth reduction for old hardwoods. The 7%
difference between young and old hardwoods grew to 17% during extreme drought.
While those age-related
differences may appear fairly minor, when applied at the global scale they
could have "huge impacts" on regional carbon storage and the global
carbon budget, according to the study authors. That's especially true in
temperate forests that are among the largest carbon sinks worldwide.
In the study,
age-related drought-response differences in conifers were smaller than in
hardwoods, likely because needle-bearing trees tend to inhabit more arid
environments, the researchers say.
The current study was
part of Au's doctoral dissertation at Indiana University, and he continued the
work after joining U-M's Institute for Global Change Biology, which is based at
the School for Environment and Sustainability.
The new study is a
synthesis that represents the net effects of thousands of trees in diverse
forests across five continents, rather than focusing on single forest types. In
addition, the new study is unique in its focus on trees in the upper forest
canopy, which reduces the confounding effects of tree height and size,
according to the authors.
In addition to Au and
Maxwell, the study's authors include Scott Robeson, Sacha Siani, Kimberly
Novick and Richard Phillips of Indiana University; Jinbao Li of the University
of Hong Kong; Matthew Dannenberg of the University of Iowa; Teng Li of
Guangzhou University; Zhenju Chen of Shenyang Agricultural University; and
Jonathan Lenoir of the UMR CNRS 7058 at Université de Picardie Jules Verne in
Amiens, France.
Study authors received
support from Indiana University, the Hong Kong Research Grants Council and the
National Natural Science Foundation of China. The research was supported in part
by Lilly Endowment Inc., through its support for the Indiana University
Pervasive Technology Institute.
https://www.sciencedaily.com/releases/2022/12/221201123148.htm
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