g. katul1,2,*, s. manzoni3, s. palmroth1, a. porporato2,1 ... · pdf fileg. katul1,2,*, s....
TRANSCRIPT
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G. Katul1,2,*, S. Manzoni3, S. Palmroth1, A. Porporato2,1, D. Way1,4 & R. Oren1
1Nicholas School of the Environment & 2 Department of Civil and Environmental Engineering, Duke
University, Durham, North Carolina, USA; 3Department of Physical Geography, Stockholm University,
Sweden; 4Department of Biology, University of Western Ontario, Ontario, Canada
*Email: [email protected]
Alpine Summer School, Course XXIII
Valsavarenche, Valle D’Aosta, Italy, 22 June – 1 July, 2015
Special Lecture on the Economics of Leaf-Gas Exchange
(Thursday, June 25, 2015)
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Jan Baptist van Helmont coined the word ‘gas’ in the 17th century and noted that ‘gas sylvestre’ (carbon dioxide) is given off by burning charcoal.
He also investigated water uptake by a willow
tree, thereby pioneering some of the earliest experiments on gas transfer (after the seminal work of Edme Mariotte around 1660).
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Centuries later, van Helmont’s activities converged into a modern-day story:
Atmospheric CO2 (ca) is rising largely due to
fossil fuel combustion, and the ability of terrestrial plants to uptake CO2 is currently a leading mitigation strategy to offset this rise.
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WATER CYCLE: Increase in continental scale
runoff because plant stomata open less as CO2 concentrations increase (Betts et al., 2007; Gedney et al., 2006).
H2O CO2
CARBON CYCLE: Reduced stomatal conductance - predicted to lead to saturation of CO2 uptake by plants, contributing to acceleration of global warming (Cox et al., 2000).
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Land plants appeared in the fossil record some 500 Million years ago, presumably evolving from aquatic chlorophyte algae.
Compared to aquatic systems, the terrestrial environment posed major challenges to terrestrial plant survival.
From: sharonhs-taxa-2013-p3.wikispaces.com
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To exchange gas with a desiccating atmosphere (a necessary requirement for carbon fixation via photosynthesis), plants needed to engineer systems to bring water to the exchanging tissue.
Connections between plant hydraulic structure (water delivery system) and function (carbon fixation) must exist.
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Plants evolved a coordinated photosynthetic – hydraulic machinery, where the maximum capacity of the hydraulic machinery reflects tradeoffs between safety and efficiency.
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Leaf photosynthesis to be minimum of 3 rates:
min
E
c c
s
J
f J
J
RuBP regeneration-limited
Rubisco-limited
Sucrose-limited
*
1
2
i
c
i
Cf
C
Mathematical Form:
M. Calvin
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*
1
2
i
c
i
Cf
C
( )c s a if g C C
Farquhar model: Biochemical Demand
Mass Transfer (Fickian): Atmospheric Supply
2 equations,
3 unknowns: fc, gs, Ci
A. Fick
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Francis Darwin already noted in 18981 that
“transpiration is stomatal rather than curticular, so that other things being equal, the yield of watery vapour depends on the degree to which stomata is open, and may be used as an index to their condition”.
So, what drives stomatal opening?
Darwin, F. (1898), Observations on Stomata. Proceedings of the Royal Society of
London (1854-1905). 1898-01-01. 63:413–417.
www.evolution.Berkeley.edu
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)()()()( 4321
max,
al
s
s cffDfPARfg
g
No synergistic interactions
One of the earliest empirical
approaches (Jarvis, 1976)
Jarvis, P., 1976, The Interpretation of the Variations in Leaf Water Potential and
Stomatal Conductance Found in Canopies in the Field, Phil. Trans. R. Soc.
Lond. B vol. 273, 593-610
P. Jarvis
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1
1 21 1 2 1; 1c c
a a o
m m Dg f RH b g f b
c c D
‘Ball-Berry’
(Collatz et al., 1991)
Leuning (1995)
Two well-known formulations that fit a wide range of data:
Ball-Berry - allowed interactions between the biosphere and
atmosphere when ‘greening’ climate models (Sellers et al.,
1996).
Note the linear relation between g and fc/ca
SUPPORTED BY A LARGE CORPUS OF LEAF-LEVEL DATA
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Science, Vol. 275, 24 January, 1997
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Climate projections for warming scenarios:
Usually predict invariant air relative humidity (RH). If so, then vapor pressure deficit (D) increases exponentially with increasing temperature (T) as discussed in Kumagai et al. (2004).
𝐷 = 𝑒∗(𝑇)(1 − 𝑅𝐻)
Kumagai, T., G. G.Katul, A. Porporato, T. M.Saitoh, M. Ohashi, T. Ichie, M.
Suzuki, 2004, Carbon and water cycling in a Bornean tropical rainforest under
current and future climate scenarios, Advances in Water Resources, 27, 135-150
1
1 21 1 2 1; 1c c
a a o
m m Dg f RH b g f b
c c D
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Stomatal conductance as a “compromise between the need to provide a passage for assimilation and the prevention of excessive transpiration” (Cowan and Troughton, 1971; Givnish, 1976).
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c
e s
Carbon Gain f
Water Loss f a g D
Define the instantaneous:
Objective: maximize C gain
Dalton’s Law
Lagrange
Multiplier
T
sc dtgf0
Subject to soil moisture availability constraint
sesc gfgfH Hamiltonian:
H has to be maximized `
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0)()(
sesc
s
gfgfg
Problem mathematically CLOSED - Analytical solution
accounting for all non-linearities in the fc-Ci curve and
photosynthesis limitations was derived elsewhere (Katul et
al., 2010).
*
1
2
i
c
i
Cf
C
( )c s a if g C C
Biochemical Demand
Atmospheric Supply
Optimality Hypothesis
(Temporal changes in λ neglected at time scales faster than soil moisture changes)
Hamiltonian H
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Analytical foresight: Photosynthesis model simplified (as Hari et al., 1986; Lloyd, 1991)
Linearized biochemical demand
function: *
2
1
i
i
c cc
f
aaai scccc 22 )/(
s= assumed constant
(e.g. determined from stable isotopes)
P. Hari
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Maximize Hamiltonian given by:
Dag
scg
cggfgfgH s
as
assescs
21
1)()()(
)()(
21
1
as
assc
scg
cggf
Carbon gain Water loss
fc(gs)
gs
Downward
concavity!
fe(gs) Correct downward concavity & saturation
with increased CO2
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Upon differentiating H(gs) with respect to gs and setting it to zero (Hari et al., 1986; Lloyd, 1991; Katul et al., 2009):
1/2
1/21a
i
a
a
c
cD
c
1/ 2
1
2
1 a
a
sgD
c
sc a
1
2
c a a
a
f c a Dcsc
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Combine the formulation for conductance and photosynthesis (Katul et al., 2010)
2/1 Da
c
c
fg a
a
c
1
1 21 1 2 1; 1c c
a a o
m m Dg f RH b g f b
c c D
Linear Biochemical Demand Function
Leuning Ball-Berry
See Medlyn et al. (2011) for a variant on the light-limitation version.
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Proportionality of gc and A
(see also Hari et al., 2000, Aus. J. Plant Phys.)
Pa
lmro
th e
t a
l., 1
99
9, O
eco
log
ia
2/1 Da
c
c
AEDg a
a
s
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~40 species that include diffuse
porous, ring-porous, non-porous, and
desert shrubs.
Stomatal responses to vapor pressure deficit: Is the D-1/2 consistent with literature responses?
𝐺𝑠
𝐺𝑠𝑟𝑒𝑓= 1 − 𝑚 𝑙𝑜𝑔(𝐷)
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Empirical findings of Oren et al (1999):
Analysis on more than 40 species found that
m=0.5-0.6 when fitting leaf and tree conductance data using:
1/2
1
2
1 a
a
ca
a sg
Dc a
RECALL: OPTIMAL SOLUTION
𝑔
𝑔𝑟𝑒𝑓= 1 − 𝑚 𝑙𝑜𝑔(𝐷)
𝑔𝑟𝑒𝑓 defined at D=1 kPa, high light levels and ample soil moisture
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1/211 (1 1/ 2log( ))
1 log( ); 11 2 1
a
ref
g DD
g
c
a
1/ 2
1
2
1a
refaca
a sg
c a
1 log(m )ref
gD
g Compare to Oren et al. (1999):
Linear optimization model with D=1 gives reference conductance
m=0.5-0.6
1
1/ 2
1
( )
1/ 2log( )1
!
11 log( ) ..
2
n
n
n
f D D
D
n
D
RAPIDLY CONVERGING
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Fagus crenata
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Drop in
Transpiration
VPD
Transpiration
𝑓𝑒 = 𝑔 𝐷 𝐷
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𝑓𝑒 ∝ 𝑓 𝐷 𝐷
Driving force for leaf transpiration:
leaf conductance: 𝑔 ∝ 𝑓 𝐷
∝ 𝐷
Leaf transpiration:
Optimization models and apparent feed-forward mechanism
Apparent feedforward mechanism is a shutdown in 𝑔 that is faster than the
increase in driving force 𝐷 so that with increased 𝐷, transpiration losses are
reduced to prevent leaf de-hydration.
All else being the same, this process should be reversible.
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Apparent feed-forward mechanism:
Literature:
Rare (at best), reversibility rarely tested.
CAN NECESSARY CONDITIONS TO
OBSERVE IT USING BE ESTABLISHED
USING OPTIMAL STOMATAL
THEORIES?
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Apparent feed-forward mechanism For Rubisco-limited Photosynthesis
𝑓𝑒 = 𝑎𝐷𝛼1
𝛼2 + 𝑠𝑐𝑎−1 +
𝑐𝑎
𝑎𝜆𝐷
12
= 𝑎𝛼1
𝛼2 + 𝑠𝑐𝑎−𝐷 + 𝐷1/2
𝑐𝑎
𝑎𝜆
1/2
𝜕𝑓𝑒
𝜕𝐷= −1 +
1
2
𝑐𝑎
𝑎𝜆
1/2
𝐷−1/2 = 0 𝐷𝑐𝑟𝑖𝑡 =1
4
𝑐𝑎
𝑎𝜆
𝐷 > 𝐷𝑐𝑟𝑖𝑡 =1
4
𝑐𝑎
𝑎𝜆
Hence, apparent feed-forward mechanism discussed in Monteith (1995) occurs when
Solve for D:
Recall that linearized solution yields for leaf transpiration:
Increasing D increases then decreases leaf transpiration (hence a maximum):
N.B. Some studies (e.g. Buckley, 2005) already speculated a linkage
between the apparent feed-forward mechanism and stomatal optimization.
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Apparent feed-forward mechanism: Revisiting Bunce (1997) data
Comparison between
optimization model
calculations of stomatal
conductance (g)
and transpiration rate
(fe) and the data from
Bunce (1997) for the
onset of a feed-forward
mechanism in three
leaves of Abutilon
theophrasti plotted
using different symbols.
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Conditions of experiments (i.e. how D is generated) affect to what degree the apparent feedforward mechanism is observed.
Fix Temperature but
vary vapor pressure
Fix vapor pressure but
vary temperature
Rubisco Rubisco RuBP
RuBP
From: Vico, G.,S. Manzoni, S. Palmroth, M. Weih, and G.G. Katul, 2013, A perspective on optimal leaf
stomatal conductance under CO2 and light co-limitations, Agricultural and Forest Meteorology, 182-
183, 191-199
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Other optimization theories
Prentice et al. (2014):
Idea: Plants tend to operate at an optimal 𝑐𝑖
𝑐𝑎 and
maintain it constant.
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1/2
1/21a
i
a
a
c
cD
c
Optimization models and ratio of intercellular to ambient CO2
This ratio only holds when plants maximize their carbon gain
for a given water loss. It is independent of stomatal operation
as the stomatal aperture here is already at optimum.
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Nonlinear response of ci/ca with D
1/2
1/21a
i
a
a
c
cD
c
Nonlinear response
Linear response
Eucalyptus Pine Seedling Pine Canopy
Stable
Isotopes
Gas
exchange
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CG=constant conductance
CC = constant ci/ca
BB = Ball-Berry model
LE = Leuning model
JO = Jarvis-Oren model
LO = Linear optimality
AT ET
Way, D., et al. 2011, Journal of Geophysical Research, 116, G04031, doi:10.1029/2011JG001808
Seasonal Carbon balance
MODELS
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Extension to include Mesophyll conductance and salt stress
Revise theories to accommodate
water and salt stress under
ambient and elevated CO2.
Manzoni, S., G. Vico, G.G. Katul, P.A. Fay, H.
W. Polley, S. Palmroth, and A. Porporato,
2011, Optimizing stomatal conductance for
maximum carbon gain under water stress: a
meta-analysis across plant functional types
and climates, Functional Ecology, 25, 456-
467
Volpe, V., S. Manzoni, M. Marani, and G.G.
Katul, 2011, Leaf conductance and carbon
gain under salt-stressed conditions, Journal
of Geophysical Researach, 116, G04035,
doi:10.1029/2011JG001848
Blue-print on how to proceed sketched in:
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Linearized formulation
𝑔𝑒𝑓𝑓 =𝑔𝑚𝑔𝑠
𝑔𝑚 +𝑔𝑠 CO2 pathway (Mesophyll & Stomatal)
H2O pathway (only stomatal)
𝜕𝑔𝑠
𝜕𝑔𝑚= 0 Assume
𝑔𝑠 =𝑎1𝑔𝑚
𝑎1 + 𝑔𝑚(𝑎2 + 𝑠𝑐𝑎)−1 +
𝑐𝑎 − 𝑐𝑝
𝑎𝜆𝐷
𝑔𝑠
Fresh
Salt
Fresh
Salt
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Interestingly, 𝑔𝑠 − 𝑓𝑐 form is
maintained as with empirical models.
2/1
Da
cc
c
fg
pa
a
cs
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𝑔𝑠 =𝑎1𝑔𝑚
𝑎1 + 𝑔𝑚(𝑎2 + 𝑠𝑐𝑎)−1 +
𝑐𝑎 − 𝑐𝑝
𝑎𝜆𝐷
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PDF(s)
s
Water availability was not considered in the stomatal optimization
theories. Soil moisture content varies across a wide range of time
scales.
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Process-based optimal control problem
1) Objective: maximize photosynthesis (A) over a
period T
2) Control: stomatal conductance to CO2 (gC)
3) Constraint: soil water is limited
Hypothesis:
Water use strategies are optimal in a given environment
(idea pioneered by Givnish, Cowan and Farquhar)
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T
T
JdtttxtgAJ 0
,,
ttxLttgEtRdt
dxnZr ,,
ttxtgftttxtgAttxtgH ,,,,,,
,0
g
f
g
A
g
H .
x
H
dt
d
Hydrologic
Balance
Objective
Function
Hamiltonian
Derivation of
optimal g(t)
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T
c dtgA0
Objective: maximize
Soil moisture changes slowly compared to light and VPD
Soil moisture is assumed constant
Optimal stomatal conductance
1
aD
ckg a
C
λ is constant, but undetermined! (classical solution by Cowan and Farquhar; Hari and Mäkelä)
0
E
At
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T
c dtgA0
Objective: maximize
s
R E
QLgERdt
dsnZ cr
Subject to the
constraint
L
Zr
Q
Marginal water use efficiency
t
Optimal stomatal conductance
λ is defined by the boundary conditions of the optimization (Manzoni et al. 2013, AWR)
1
aD
ckg a
C with time
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λ increases as drought progresses across
species, ecosystems, and climates
(Manzo
ni et al., 2011, F
unctional E
col)
Water stress
Wa
ter
use
eff
icie
ncy
Ψ
λ/λ
ww
eww
-ψ
λ
λww
-ψ
gc
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to satisfy the carbon demand
1-D Richard’s equation with H2O sinks
solved by Finite Element Methods
Stem hydraulics – based on cavitation
curves from Sperry et al. (2000).
Maximum H2O loss from carbon demands
of the leaf.
Stomatal shut-down: From Sperry - Critical
pressure
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To assess the maximum hydraulic transport capacity supporting photosynthesis, the focus is on maximum transpiration rate E in the xylem system under WELL-WATERED SOIL conditions.
Detailed representations available1 – but simpler ones needed to interpret the numerous data sources
1Bohrer, G., H. Mourad, T. A. Laursen, D. Drewry, R. Avissar, D. Poggi, R. Oren, and G. G. Katul,
2005, Finite-Element Tree Crown Hydrodynamics model (FETCH) using porous media flow within
branching elements - a new representation of tree hydrodynamics, Water Resources Research, 41,
W11404, doi:10.1029
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~0S
L
g ( )P L
LLPgE
Simplifying assumptions:
1) Focus on maximum rates, attained
under well-watered conditions
→ ΨS-ΨL~-ΨL
2) Assume that cavitation occurs first
in the most distal parts of the plant (hydraulic segmentation, Zimmerman,
Can J Bot 1978)
→ ΨX~ΨL at the site of cavitation
3) Gravitational effects are negligible with
respect to frictional pressure losses
From: Manzoni, S., G. Vico, G. Katul, S. Palmroth, R.B. Jackson, and A. Porporato, 2013, Hydraulic limits on
maximum plant transpiration and the emergence of the safety-efficiency trade-off, New Phytologist, 198, 169-178
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~0S
L
g ( )P L
1
50
, 1
a
LmaxPLP gg
Data
fo
r A
lnu
s c
ord
ata
(To
gn
ett
i a
nd
Bo
rgh
ett
i 1
99
7)
- (MPa)
Pg
( )
X
X
50
a
0 1 2 30
0.5
1
Vulnerability curve
Xylem conductivity declines with
decreasing water potential due
to cavitation and embolism
-ΨL
gP(Ψ
L)/
gP,m
ax
From: Manzoni, S., G. Vico, G. Katul, S. Palmroth, R.B. Jackson, and A. Porporato, 2013, Hydraulic limits on maximum plant transpiration
and the emergence of the safety-efficiency trade-off, New Phytologist, 198, 169-178
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Maximize E with respect to ΨL
amaxL a
1
50, 1
L,maxL,maxPmax gE
maxPL,maxP gag ,
11 0 2 4 60
1
2
0 2 4 60
0 2 4 60
0.1
0.2
|L| (MPa)
L,max
Emax
High gP,max
, low |50
|
Low gP,max
, high |50
|
gP
(m
3 d-1 M
Pa
-1)
S-
L~-
L
E (
m3 d
-1)
4
2
(MP
a)
0 LLP
LL
gd
d
d
dE
Maximum E is computed as
3 parameters: gP,max, a, Ψ50
amax
1PLC
% loss of
conductivity
From: Manzoni, S., G. Vico, G. Katul, S. Palmroth, R.B. Jackson, and A. Porporato, 2013,
Hydraulic limits on maximum plant transpiration and the emergence of the safety-efficiency
trade-off, New Phytologist, 198, 169-178
LLPgE
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Individual plant
transpiration Transpiration per unit
sapwood area
𝐸𝑚𝑎𝑥 = 𝑔𝑃,𝑚𝑎𝑥𝜓 50
𝑎 − 1 1−1/𝑎
𝑎
Varies between
0.5 and 0.7.
550 species
and cultivars
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Correlations among plant traits suggest
evolutionary convergence towards a
balanced water-carbon economy.