Scientists flip the script, revealing trees in wetter regions are more sensitive to drought
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Scientists have long debated whether arid conditions make
trees more or less resilient to drought. It seems intuitive that trees living
at their biological limits will be most vulnerable to climate change, since
even just a little extra stress could tip them past the brink. On the other
hand, these populations have adapted to a harsher setting, so they might be
more capable of withstanding a drought.
According to a new study in the journal Science by researchers at UC Santa
Barbara and UC Davis, greater water availability could “spoil” trees by
reducing their adaptations to drought. “And that’s really critical to
understand when we’re thinking about the global vulnerability of forest carbon stocks
and forest health,” said ecologist Joan
Dudney, an assistant professor at UCSB’s Bren School of
Environmental Science & Management and in the Environmental Studies
Program. “You don’t want to be a ‘spoiled’ tree when facing a major drought.”
Joan Dudney's research focuses on the causes and consequences of large-scale changes in terrestrial ecosystems, such as forests and grasslands. These include infectious disease, pest outbreaks, invasive plants and climate change.
Dudney and her co-authors expected trees growing in the
most arid regions to be more sensitive to drought, since they’re already living
at the edge of their limits. What’s more, climate change models predict that
these regions will experience more rapid drying than wetter regions. This shift
in climate could expose trees to conditions beyond their adaptive capacity.
To measure drought sensitivity, the authors analyzed 6.6
million tree ring samples from 122 species worldwide. For each year, they
measured whether the tree grew faster or slower than average based on its ring
width. They linked these trends with historic climate data, including
precipitation and temperature.
The team then compared drought responses across different
regions. “As you move to the drier edge of a species’ range, trees become less
and less sensitive to drought,” said lead author Robert
Heilmayr, an environmental economist also in the Environmental
Studies Program and at the Bren School. “Those trees are actually quite
resilient.”
Robert Heilmayr is environmental economist who studies
the environmental, social and economic impacts of conservation. Robert combines
methods of causal inference from economics with data made possible through
Earth observation to detail how society interacts with nature.
Dudney, Heilmayr and their co-author Frances Moore were
inspired, in part, by the work of UCSB professor Tamma Carleton on the effects
climate change has on human populations. “This paper highlights the value of
cross-disciplinary scientific work,” added Moore, an associate professor at UC
Davis. “We were able to adapt methods from economics originally developed to
study how people and businesses adjust to a changing climate and apply them to
the ecological context to study forest sensitivity to drought.”
“A heatwave is likely to kill more people in a cool place
like Seattle than in hotter cities like Phoenix,” Heilmayr said. The Southwest
is already quite hot, so heatwaves there are scorching. But the region’s cities
are adapted to an extreme climate, he points out. Now we know that forests
display similar trends.
Unfortunately, warmer regions are slated to get
disproportionately drier in the coming decades. “There is a pretty large
portion of species’ ranges that are going to face a completely novel climate,
something that those species don’t see anywhere in their range today,” Heilmayr
explained. The authors found that 11% of an average species’ range in 2100 will
be drier than the driest parts of their historic range. This increases to over
50% for some species.
“Broadly, our research highlights that very few forests
will be unaffected by climate change,” Dudney said. “Even wetter forests are
more threatened than we thought.”
But there is a flip side of the coin. Species have a
reservoir of drought-hearty stock in the drier parts of their range that could
bolster forests in wetter areas. Previous research out of UCSB revealed
that many species do have the capacity to adapt to environmental change.
However, those researchers also found that trees migrate slowly from one
generation to the next. That means human intervention — such as assisted
migration — may be necessary in order to take advantage of this genetic
diversity.
Whether your Christmas trees grow in a dry or wet region,
they’ll likely experience growth declines in the future. But understanding how
trees will respond to climate change can help ensure the future of the
Tannenbaum and its wild counterparts.
