Ronald P. NeilsonUSDA Forest Service

Pacific Northwest Research Station

Corvallis, OR, USA

(and a cast of many)

Vegetation Distribution

and Climate Change in

the West

Challenges for Restoration

Under Rapid Climate Change

• Function – Services?– Wetter or Drier?

• Woody Expansion?

• Dieback?

• Infestation

• Loss of Water Resources

• Diversity – Services?– A Superstructure to maintain Function

– Functional Types – Functional Groups

– Species and Community Assembly Rules

– Migration• Invasion

• Establishment

Source: OSTP

Ocean-Climate Regime Shifts

1972-77

1988-89

1940-47

Variations of the Earth’s Surface Temperature:

1000 to 2100

• 1000 to 1861, N.

Hemisphere, proxy data;

• 1861 to 2000 Global,

Instrumental;

• 2000 to 2100, SRES

projections

High Warming

Moderate Warming

Small Warming

Similar to Glacial –

Interglacial

Temperature Change

CSIRO

MIROC

HAD

A2 A1B B1

Change in Mean Monthly Temperature

(Degrees C)

2070-2099 vs 1961-1990

Climate Scenario UncertaintiesModel Uncertainty versus Emissions Uncertainty

(IPCC – Fourth Assessment Report Scenarios)

A2 A1B B1

CSIRO

HAD

MIROC

Percent Change in Precipitation

2070-2099 vs 1961-1990

Regional Precipitation Uncertainty:

North Wetter, South Drier

Long-Term

Changes in Distribution

and

Structure

Communities and Ecosystems:

MacMillan

RH Whittaker - New York, 1975

Major Biome BoundariesEcotones in Space – Ecotones in Time (Threshold, Tipping Point)

Water Limited

Leaf Area

Carrying Capacity

All else follows!

Future Thermal Impacts

• Longer Growing Season

• Migration

• Natives Invade Natives

• Release of Frost Limitations

• Loss of Alpine

• Expansion of Subtropics

• Great Basin Thresholds

• Expansion of Tropics

Current Climate

GFDL Future Climate

Thermal ZonesMAPSS Simulations Boreal

Temperate

Subtropical

Tropical

MAPSS Simulated Vegetation Distribution

Ecotones in Space

Emergent Properties LAI, Ecotones, Runoff

Neilson,R.P. 1995. A model for predicting continental-scale vegetation

distribution and water balance. Ecological Applications 5:362-385.

Water LimitedLeaf Area

Carrying Capacity

All else follows!

To my Knowledge

Only three

Process-based

Biogeography

Models Published!

DGVM (Full Structure)

MAPSS MC1, BIOMAP

DOLY SDGVM

BIOME LPJ

Current Climate Future Climate(CGCM1)

Future Woody and Grass Expansion in the West

Enhance Carbon Storage, and

Catastrophic Wildfire, But…

Woodland ExpansionMAPSS Simulation

Bachelet,D., R.P.Neilson, J.M.Lenihan, and R.J.Drapek. 2001. Climate change effects on

vegetation distribution and carbon budget in the U.S. Ecosystems 4:164-185.

Desert

Forest

(Green)

Woodland

Savanna

(Brown)Shrubland

Grassland

Natives Invading NativesMAPSS Simulation

Current Climate

Explosive Great Basin Diversity

Future Climate(CGCM1)

Bachelet,D., R.P.Neilson, J.M.Lenihan, and R.J.Drapek. 2001. Climate change effects on

vegetation distribution and carbon budget in the U.S. Ecosystems 4:164-185.

MC1 Simulate Historical Vegetation Distribution

Mode Vegetation Type (1961 -1990)

MC1 Simulate Future Vegetation Distribution

Mode Vegetation Type CSIRO_a2

MC1 Simulate Future Vegetation Distribution

Mode Vegetation Type HADLEY_a2

MC1 Simulate Future Vegetation Distribution

Mode Vegetation Type MIROC_a2

Vegetation Carbon (Percent Change) CSIRO_a2

Vegetation Carbon (Percent Change) HADCM3_a2

Vegetation Carbon (Percent Change) MIROC_a2

Biomass Consumed by Fire (Percent Change) CSIRO_a2

Biomass Consumed by Fire (Percent Change) HADCM3_a2

Biomass Consumed by Fire (Percent Change) MIROC_a2

Near -Term

Changes in Variability

and

Disturbance

Some areas are projected to become wetter,

others drier with an overall increase projected

Annual mean precipitation change: 2071 to 2100 Relative to 1990

The Water Cycle moves most of the energy from the Tropics to the Poles!

August 6, 2008

September 14, 2008

The Water Cycle moves most of the energy from the Tropics to the Poles!

The Water Cycle moves most of the energy from the Tropics to the Poles!

June 4, 2009

The Water Cycle moves most of the energy from the Tropics to the Poles!

June 6, 2009

July 12, 2009

The Water Cycle moves most of the energy from the Tropics to the Poles!

Western Regions

1900 1910 1920 1930 1940 1950 1960 1970 1980 1990 2000

Wet

P

DS

I

D

ry

-4

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0

2

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Are

a B

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10

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50

60

Palmer Drought Severity Index (5 year running average)

Simulated Area Burned (MC1 Model) (5 year running average)

Spearman Rank Correlation Coefficient -0.59***

J LENIHAN 9/11/03

El Niño

1983 1998

Drought and Fire in the West(Simulated Fire, no Fire Suppression)

The MAPSS Team, unpublished

Summer

Humidity

Gradient

Arizona Monsoon

(July – August

Polar Front

Wet vs. Dry Winter

Moisture Zones

Mitchell,V.L. 1976. Journal of Applied Meteorology 15:920-927.

Neilson & Wullstein. 1983. Journal of Biogeography 10:275-297.

Precipitation (Red Transect)

Tentative Changes

• Winter Cyclonic Storms

• Wetter North, Drier South

• Seasonality Shifts

•Expansion of Arizona Monsoon

Global Cooling

Global Warming

Global Cooling

Global Warming

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Variation in Leaf Carbon (g/m2)

OR / WA / ID (SRES A2 Scenarios)

4K-hist 8K-hist 8K-Miroc 8K-Had 8K-CSIRO

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Variation in Leaf Carbon (g/m2)

AZ / NM / CO (SRES A2 Scenarios)

4K-hist 8K-hist 8K-Miroc 8K-Had 8K-CSIRO

Summary

• Warmer temperatures will push alpine and subalpine communities off the tops of the mountains

• Wetter winters in the north, drier in the south with great uncertainty and variability inbetween

• The Arizona Monsoon will very likely be enhanced, although the GCMs are very weak in simulating this

• Thus, lower elevational forest ecotones could go down at southern latitudes (within the Monsoon region), even while deserts could become hotter and either more or less xeric.

• Huge Uncertainties:

– CO2 effect on enhanced woody expansion.

– Near-Term Variability, Establishment and Disturbance

Management Implications(personal musings)

• Management Goals face an uncertain Future

– The Future will NOT echo the Past

• Instead,… Manage Change, per se

– Desired function may supercede ‘Desired future condition’

• Improve resilience of ecosystems to rapid change,

e.g.

– Keep forest density below water-limited carrying capacity

– Plant diversity rather than homogeneous monocultures

• Restoration efforts confront:

– a) establishment bottlenecks,

– b) invasions,

– c) functional communities

Acknowledgements

Pacific Northwest Research Station

Managing Disturbance Regimes Program

Oregon State University

Colorado State University

University of Montana

National Center for Atmospheric Research

IRI, International Research Institute for

Climate Prediction

CEFA/DRI Program for Climate, Ecosystem

And Fire Applications

National Fire Plan

USFS Climate Change Program

NSF, EPA, DOE, EPRI, USGS-BRD

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Variation in Leaf Carbon (g/m2)

Western States (SRES A2 Scenarios)

4K-hist 8K-hist 8K-Miroc 8K-Had 8K-CSIRO