grassland-shrubland transitions: part 2. lateral flux of water, sediment, nutrients percolation...
DESCRIPTION
How does connectivity impact transport vectors (wind and water) and the distribution of nutrients to impact state change? Water flow at state boundaries The "Scraped Site" (1991) Mueller et al 2007 Okin et al 2001Okin et al 2006TRANSCRIPT
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Grassland-shrubland transitions: Part 2
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Lateral flux of water, sediment, nutrients Percolation
Schlesinger et al. (1990) “islands of fertility” or “Jornada” desertification model
Not clear how perennial grasses are lost from the ecosystem—a focus of long-term work since LTER IV
Feedback Feedback
Disruption of perennial grass cover, shrubs invade
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How does connectivity impact transport vectors (wind and water) and the distribution of nutrients to impact state change?
Water flow at state boundaries
The "Scraped Site" (1991)
Mueller et al 2007
Okin et al 2001 Okin et al 2006
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Do grasslands cross critical thresholds at low, but positive, levels of grass cover?
Driver-control model: grass driven extinct directly by grazing/drought
Feedback-control model: critical threshold of grass cover below which soil erosion/hydrologicalfeedbacks drive remaining grass cover extinct
Driver
Gras
s cov
er/p
rodu
ction
Bestelmeyer et al, 2013, Ecology Letters
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Do changes in connectivity cause desertification?
Okin et al. 2009
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Aeolian Transport – Sand Sheet and Gap Size
Okin et al 2006
C G P T0
0.1
0.2
0.3
0.4
0.5 Dry (1999-2003)Wet (2004-2012)
Vegetation type
Mea
n ho
rizon
tal s
edim
ent fl
ux
(g/c
m/d
)
M012345678
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Experimental evaluation of threshold modelswith respect to aeolian transport Hypothesis 1(b) As bare gap sizes increase, a connectivity threshold level is reached that sets the stage for nonlinear increases in the spatial extent of shrub dominance owing to negative effects on grass persistence [Hypothesis 1(a)] and positive feedbacks to shrub establishment and growth.
Split-treatment (Upwind-Downwind) experiment begun in 20043 Blocks with 4 (split) treatments and 1 control in each
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1) Vegetation cover will make horizontal flux increase both upwind and downwind
2) Enhanced flux will impact soils upwind and downwind and vegetation downwind
3) Thresholds will exist where system becomes "lossy" and state change occurs downwind.
Specific expectations
(As of 2014)Upwind
Veg CoverControl 0.3825% Removal 0.2350% Removal 0.2275% Removal 0.19100% Removal 0.06
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Horizontal Flux
0.00 0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40 0.450
0.5
1
1.5
2
2.5
3
3.5
4 2005
Fractional Perennial Vegetation Cover
Horiz
onta
l Flu
x (g
cm
-1 d
-1)
0.00 0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40 0.450
0.5
1
1.5
2
2.5
3
3.5
4 2012
Fractional Perennial Vegetation Cover
Horiz
onta
l Flu
x (g
cm
-1 d
-1)
• Horizontal flux does not scale monotonically with vegetation cover in all years.
• It's becoming increasingly common to see lower flux at the 100% removal site where cover ~6%
• Incidentally, these data have also been useful in calibrating a connectivity-based horizontal transport model
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Horizontal Flux
This indicates a severe disturbance may be self-limiting, whereas a more moderate disturbance may have a comparable effect in the long term
Upwind treatment at 100% removal has eroded to the
less-erodible B horizon
With time, the flux on the treatment downwind of the 100% removal has reached the level of the the removal treatment itself
No decrease post-2007
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How does enhanced flux influence vegetation?With time, the flux on the treatment downwind of the 100% removal has reached the level of the the removal treatment itself
Potential mechanisms:Abrasion? Burial/Dynamic Surface? Nutrients?
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Burial or Dynamic Surface?
Upwind Downwind Upwind Downwind
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Nutrients
Li et al. 2007Threshold?
Resampled Summer, 2013
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• Aeolian processes have an important impact on vegetation and nutrients on both directly and indirectly impacted sites
• Evolution of the soil over the long term adds an unexpected wrinkle
• We see nonlinear decreases in grass persistence [1(a)] which supports existence of a feedback favoring shrubs due to increased (downwind) aeolian transport
• Mechanisms are uncertain (pending full proposal)
Conclusions at this point
Ongoing/Future Work• Analyze soil data for SOC & TN (changes in thresholds?
changes in spatial distribution of nutrients?)• UAV-derived aerial photo analysis of vegetation cover and
connectivity (better quantify grass + shrub cover/distribution)
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LTER VI Proposal, Hypothesis 1(c): Vegetation and resource losses propagate to initiate state change dynamics in downwind /downslope locations.
Connectivity-based feedback (from Okin et al. 2009)
• Design of this experiment has been difficult:• Replication vs. size• Wind and/or water?• Connectivity or pattern?
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LTER VI Proposal, Hypothesis 1(c): Vegetation and resource losses propagate to initiate state change dynamics in downwind /downslope locations.
• The plan is to conduct modeling experiments with ECOTONE-WEMO and other connectivity-based models (e.g., Stewart et al. 2014) to determine how best to design an experiment
• Considerations• Size of manipulation• Does total connectivity matter more, or how it is
arranged?• How does slope/texture/depth to B horizon matter?• Precipitation• Land Use
• The conceptual work for connecting ECOTONE and WEMO has been done, implementation and model experiments next…
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ECOTONE-WEMOModel Framework