Plant Cell & Environment,
Journal Year:
2024,
Volume and Issue:
47(9), P. 3561 - 3589
Published: Feb. 13, 2024
An
exponential
rise
in
the
atmospheric
vapour
pressure
deficit
(VPD)
is
among
most
consequential
impacts
of
climate
change
terrestrial
ecosystems.
Rising
VPD
has
negative
and
cascading
effects
on
nearly
all
aspects
plant
function
including
photosynthesis,
water
status,
growth
survival.
These
responses
are
exacerbated
by
land-atmosphere
interactions
that
couple
to
soil
govern
evolution
drought,
affecting
a
range
ecosystem
services
carbon
uptake,
biodiversity,
provisioning
resources
crop
yields.
However,
despite
global
nature
this
phenomenon,
research
how
incorporate
these
into
resilient
management
regimes
largely
its
infancy,
due
part
entanglement
trends
with
those
other
co-evolving
drivers.
Here,
we
review
mechanistic
bases
at
spatial
scales,
paying
particular
attention
independent
interactive
influence
context
environmental
changes.
We
then
evaluate
consequences
within
key
contexts,
resources,
croplands,
wildfire
risk
mitigation
natural
grasslands
forests.
conclude
recommendations
describing
could
be
altered
mitigate
otherwise
highly
deleterious
rising
VPD.
New Phytologist,
Journal Year:
2020,
Volume and Issue:
226(6), P. 1550 - 1566
Published: Feb. 17, 2020
Summary
Recent
decades
have
been
characterized
by
increasing
temperatures
worldwide,
resulting
in
an
exponential
climb
vapor
pressure
deficit
(VPD).
VPD
has
identified
as
increasingly
important
driver
of
plant
functioning
terrestrial
biomes
and
established
a
major
contributor
recent
drought‐induced
mortality
independent
other
drivers
associated
with
climate
change.
Despite
this,
few
studies
isolated
the
physiological
response
to
high
VPD,
thus
limiting
our
understanding
ability
predict
future
impacts
on
ecosystems.
An
abundance
evidence
suggests
that
stomatal
conductance
declines
under
transpiration
increases
most
species
up
until
given
threshold,
leading
cascade
subsequent
including
reduced
photosynthesis
growth,
higher
risks
carbon
starvation
hydraulic
failure
.
Incorporation
photosynthetic
traits
‘next‐generation’
land‐surface
models
greatest
potential
for
improved
prediction
responses
at
plant‐
global‐scale,
will
yield
more
mechanistic
simulations
changing
climate.
By
providing
fully
integrated
framework
evaluation
function,
improvements
forecasting
long‐term
projections
can
be
made.
Science,
Journal Year:
2020,
Volume and Issue:
368(6494)
Published: May 28, 2020
Forest
dynamics
arise
from
the
interplay
of
environmental
drivers
and
disturbances
with
demographic
processes
recruitment,
growth,
mortality,
subsequently
driving
biomass
species
composition.
However,
forest
subsequent
recovery
are
shifting
global
changes
in
climate
land
use,
altering
these
dynamics.
Changes
drivers,
disturbance
regimes
forcing
forests
toward
younger,
shorter
stands.
Rising
carbon
dioxide,
acclimation,
adaptation,
migration
can
influence
impacts.
Recent
developments
Earth
system
models
support
increasingly
realistic
simulations
vegetation
In
parallel,
emerging
remote
sensing
datasets
promise
qualitatively
new
more
abundant
data
on
underlying
consequences
for
structure.
When
combined,
advances
hold
improving
scientific
understanding
demographics
disturbances.
Science,
Journal Year:
2020,
Volume and Issue:
368(6488), P. 261 - 266
Published: April 16, 2020
Trees
are
the
living
foundations
on
which
most
terrestrial
biodiversity
is
built.
Central
to
success
of
trees
their
woody
bodies,
connect
elevated
photosynthetic
canopies
with
essential
belowground
activities
water
and
nutrient
acquisition.
The
slow
construction
these
carbon-dense,
skeletons
leads
a
generation
time,
leaving
forests
highly
susceptible
rapid
changes
in
climate.
Other
long-lived,
sessile
organisms
such
as
corals
appear
be
poorly
equipped
survive
changes,
raises
questions
about
vulnerability
contemporary
future
climate
change.
emerging
view
that,
similar
corals,
tree
species
have
rather
inflexible
damage
thresholds,
particularly
terms
stress,
especially
concerning.
This
Review
examines
recent
progress
our
understanding
how
looks
for
growing
hotter
drier
atmosphere.
Nature,
Journal Year:
2022,
Volume and Issue:
608(7923), P. 534 - 539
Published: July 13, 2022
Abstract
Forest
ecosystems
depend
on
their
capacity
to
withstand
and
recover
from
natural
anthropogenic
perturbations
(that
is,
resilience)
1
.
Experimental
evidence
of
sudden
increases
in
tree
mortality
is
raising
concerns
about
variation
forest
resilience
2
,
yet
little
known
how
it
evolving
response
climate
change.
Here
we
integrate
satellite-based
vegetation
indices
with
machine
learning
show
resilience,
quantified
terms
critical
slowing
down
indicators
3–5
has
changed
during
the
period
2000–2020.
We
that
tropical,
arid
temperate
forests
are
experiencing
a
significant
decline
probably
related
increased
water
limitations
variability.
By
contrast,
boreal
divergent
local
patterns
an
average
increasing
trend
benefiting
warming
CO
fertilization,
which
may
outweigh
adverse
effects
These
emerge
consistently
both
managed
intact
forests,
corroborating
existence
common
large-scale
drivers.
Reductions
statistically
linked
abrupt
declines
primary
productivity,
occurring
slow
drifting
towards
threshold.
Approximately
23%
undisturbed
corresponding
3.32
Pg
C
gross
have
already
reached
threshold
further
degradation
resilience.
Together,
these
signals
reveal
widespread
perturbation
should
be
accounted
for
design
land-based
mitigation
adaptation
plans.
Journal of Advances in Modeling Earth Systems,
Journal Year:
2019,
Volume and Issue:
11(2), P. 485 - 513
Published: Jan. 31, 2019
Abstract
Version
5
of
the
Community
Land
Model
(CLM5)
introduces
plant
hydraulic
stress
(PHS)
configuration
vegetation
water
use,
which
is
described
and
compared
with
corresponding
parameterization
from
CLM4.5.
PHS
updates
root
uptake
to
better
reflect
theory,
advancing
physical
basis
model.
The
new
prognostic
potential,
modeled
at
root,
stem,
leaf
levels.
Leaf
potential
replaces
soil
as
for
stomatal
conductance
stress,
used
implement
uptake,
replacing
a
transpiration
partitioning
function.
Point
simulations
tropical
forest
site
(Caxiuanã,
Brazil)
under
ambient
conditions
partial
precipitation
exclusion
highlight
differences
between
previous
CLM
implementation.
description
simulation
results
are
contextualized
list
benefits
limitations
model
formulation,
including
hypotheses
that
were
not
testable
in
versions
Key
include
reductions
moisture
biases
relative
control
both
conditions,
correcting
excessive
dry
season
implements
gradient
allows
redistribution
compensatory
utilizing
larger
portion
column
buffer
shortfalls
precipitation.
structure,
bases
on
could
have
significant
implications
vegetation‐climate
feedbacks,
increased
sensitivity
photosynthesis
atmospheric
vapor
pressure
deficit.
Science,
Journal Year:
2020,
Volume and Issue:
368(6493), P. 869 - 874
Published: May 21, 2020
Thermal
sensitivity
of
tropical
trees
A
key
uncertainty
in
climate
change
models
is
the
thermal
forests
and
how
this
value
might
influence
carbon
fluxes.
Sullivan
et
al.
measured
stocks
fluxes
permanent
forest
plots
distributed
globally.
This
synthesis
plot
networks
across
climatic
biogeographic
gradients
shows
that
dominated
by
high
daytime
temperatures.
extreme
condition
depresses
growth
rates
shortens
time
resides
ecosystem
killing
under
hot,
dry
conditions.
The
effect
temperature
worse
above
32°C,
a
greater
magnitude
thus
risks
loss
stocks.
Nevertheless,
are
likely
to
remain
higher
moderate
if
they
protected
from
direct
impacts
such
as
clearance,
logging,
or
fires.
Science
,
issue
p.
869
Ecology Letters,
Journal Year:
2018,
Volume and Issue:
21(10), P. 1552 - 1560
Published: Aug. 19, 2018
The
mechanisms
governing
tree
drought
mortality
and
recovery
remain
a
subject
of
inquiry
active
debate
given
their
role
in
the
terrestrial
carbon
cycle
concomitant
impact
on
climate
change.
Counter-intuitively,
many
trees
do
not
die
during
itself.
Indeed,
observations
globally
have
documented
that
often
grow
for
several
years
after
before
mortality.
A
combination
meta-analysis
physiological
models
demonstrate
optimal
allocation
explains
observed
patterns
delayed
provides
predictive
framework.
Specifically,
post-drought,
attempt
to
repair
water
transport
tissue
achieve
positive
balance
through
regrowing
drought-damaged
xylem.
Furthermore,
number
xylem
regrowth
required
recover
function
increases
with
size,
explaining
why
size.
These
results
indicate
resilience
drought-kill
may
increase
future,
provided
CO2
fertilisation
facilitates
more
rapid
regrowth.
