Post on 17-Jan-2016
Effects of Climate Change on Effects of Climate Change on Tundra Ecosystems Tundra Ecosystems
Greg Henry, University of British Columbia
Philip Wookey, University of Uppsala
Climate Change and Tundra Climate Change and Tundra EcosystemsEcosystems
• IntroductionIntroduction
• Conceptual issues: time and Conceptual issues: time and space scales, processesspace scales, processes
• Evidence of change: Evidence of change: observationsobservations
• Experimental results: ITEXExperimental results: ITEX
• Research needsResearch needs
• CO2 ‘fertilization’ effect (‘-factor’);
• Regional differences in global warming: greater than average warming at high northern latitudes;
• Increased deposition of airborne N-containing compounds;
• Stratospheric O3 depletion increased UV-B fluxes at the surface.
Environmental change has multiple facets
• “The past as a key to the future” Yes, but with caution!
Shaver et al., (2000) BioScience
Herbivores
Climate ChangeSnow cover
Veg
eta
tion
Oth
er
Soils
migration and invasion
disturbance regime herbivores
SOM development
species w/in initial community
litter mass, quality microbes, fauna
N availability
allocationLeaf Ps, Rs
1 day 1 yr 10 yr 100 yr 1000 yr
TIME-SCALE OF RESPONSE
Key issues – time scalesKey issues – time scales
[from Shaver et al.. (2000) BioScience]
“Typical” study length
Need to understand long-term effects
Key issues – time scalesKey issues – time scalesEcosystem C balanceEcosystem C balance
NetC uptake
bysystem
C
E
D
A
B
Time
NetC loss
toatmosphere
Harvard forest (A,B)Toolik Lake (C,D)Great Dun Fell (D,E)Colorado subalpine (C)Abisko (C)
[from Shaver et al. (2000) BioScience]
0
Vegetation cover
Soil organic matter
Nutrient stock
Unoccupied space
Cryo-processes??
Temperature gradient(30º latitude & 10º temp)
Warmer Colder
Key issues - spatial scalesKey issues - spatial scales
Geological & topographic influences - cross-cutting (regional and local scales)
Low Arctic High Arctic
Schematic comparison of low- and high-arctic Schematic comparison of low- and high-arctic tundra response to warmingtundra response to warming
Permafrost table
Water table
Organic matter(and nutrient pool)
Mineral ‘soil’or regolith
• Lateral spread• Immigration• Vertical development
• Vertical development• Community shifts
LOW ARCTIC TUNDRA
Mesic Shrub Tundra
HIGH ARCTIC TUNDRA
Polar Semi-Desert
(= + and -)
(= + and -)
Deeper active layer
2
2
14a
3
4b
55Semi-permanentsnow drift
Prevailing wind
1. Dry exposed ridges2. Mesic zonal sites3. Wet meadows4. Snowbeds a. well-drained, early-melting b. poorly-drained,
late-melting5. Streamside sites
1. Dry exposed ridges2. Mesic zonal sites3. Wet meadows4. Snowbeds a. well-drained, early-melting b. poorly-drained,
late-melting5. Streamside sites
Key issues - spatial scalesKey issues - spatial scales
[From Walker D.A. (2000) GCB]
Relations between topography and tundra plant communities
Evidence of changes in tundra Evidence of changes in tundra vegetationvegetation
• Increased abundance of shrubs – Alaska
• positive feedback with snow accumulation
• Increased growth rates of trees at treeline
• leading to greater seed production and treeline advance (?)
• Results from experimental manipulations
• International Tundra Experiment (ITEX)
International Tundra Experiment - www.itex-science.net
Experimental approaches ITEXExperimental approaches ITEX
12 years progress (ITEX Resolution, 5th December, 1990) sites in 1992;
Straightforward approach designed to encourage broad international participation;
Manipulation, monitoring, modelling (synthesis), mapping;
Bottom-up (‘ITEX species’)
Toolik Lake, Alaska
Alexandra Fiord, Ellesmere Island, Canada
Magerøya, Norway
ITEX and related experiments
Temperature/Position in range
Pro
cess
rate
North
South
Net PS
Intensity of competition
Experimental approaches –Experimental approaches –Experiments along gradientsExperiments along gradients
Alexandra Fiord, Ellesmere Island, Canada
ITEX Meta-analysis: leaf bud breakITEX Meta-analysis: leaf bud break
Arft et al. 1999
ITEX Meta-analysis of vegetative growthITEX Meta-analysis of vegetative growth
Arft et al. 1999
Short-term effects differ by growth form
ITEX synthesis II - ITEX synthesis II - Community Community responsesresponses
Deciduous shrubs
4
All shrubs
Graminoids
4
6
Bryophytes
4
Lichens
2
Litter
3
COVER CANOPY HEIGHT3
4
2
DIVERSITY (Shannon)
42
1.0
-1.0
0
-0.5
0.5
Effect-size (d)
Walker et al. Figure 3
Walker M.D. et al. (2004)
Meta-analysis
ITEX results – synthesis IITEX results – synthesis I
WarmingWarming experiments confirm sensitivity of cold region vegetation in general (e.g. Rustad et al. 2001): ITEX provides detail for tundra plants;
Growth increasedGrowth increased in general - variation among growth forms;
Phenological shiftsPhenological shifts consistent – earlier flowering;
Geography is importantGeography is important; (e.g. low vs high arctic)
Plant communities exhibit detectable detectable
responsesresponses to warming in only 3-4 3-4
years;years;
The most significant changes are: increasesincreases in deciduous shrubdeciduous shrub cover & height decreasesdecreases in cryptogamcryptogam cover decreasesdecreases in (apparent) species species richnessrichness;
ITEX results – synthesis IIITEX results – synthesis II
• effects on soil microorganism diversity effects on soil microorganism diversity and processes?and processes?
• negative feedback of increasing C:N ratio negative feedback of increasing C:N ratio (low quality litter) and stimulation by (low quality litter) and stimulation by warmth?warmth?
• use of organic vs mineral N sources by use of organic vs mineral N sources by plants and microbes: how will this change?plants and microbes: how will this change?
• effects of combined factors: COeffects of combined factors: CO22, heat, , heat, moisture, nutrients, light, season lengthmoisture, nutrients, light, season length
• Long-term changes in NEP and Carbon Long-term changes in NEP and Carbon balance?balance?
Continuing questions:Continuing questions: