Title: Adaptation, Vulnerability and Integrated Risk Assessment
1Adaptation, Vulnerability and Integrated Risk
Assessment
Asia Pacific Network for Global Change
Research Symposium on Global Change
Research March 23, Canberra
2Risk
- Can be broadly defined as the likelihood of an
adverse event or outcome - How does this relate to Article 2 of the UNFCCC?
3Article 2 UNFCCC
- Aims to prevent dangerous
- anthropogenic climate change
- by stabilising greenhouse gas emissions,
- thus allowing
- Ecosystems to adapt naturally
- Food security to be maintained
- Sustainable development to proceed
4What is dangerous climate change?
- This is a value judgement best assessed by
policymakers, stakeholders and the community.
Research can help with problem definition,
plausibility and likelihood of various aspects - Global thresholds of criticality grounded ice
sheet melts, N. Hemisphere flips to cold
conditions, Amazon wilts and burns in heat and
drought - Local thresholds of criticality any activity
where impacts become non-viable with no
reasonable substitute or the harm caused exceeds
given levels of tolerance
5Attaching likelihood
- What is the likelihood of exceeding given levels
of criticality without risk management? - What type and level of management is needed to
reduce these risks? - These questions can be assessed on a range of
scales
6Risk management
- Mitigation reduces climate hazards
- Adaptation reduces the consequences for a given
level of climate-related hazard - Adaptation may act to
- reduce harm,
- take advantage of benefits, and
- modify ongoing change processes
7Linking climate to adaptation over time
8Measuring the ability to cope
9Coping under climate change
10Four pillars of climate risk analysis
- Most systems affected by climate variability have
evolved to cope with that variability to some
extent - Climate change will mainly be felt as changes to
climate variability and extremes. - Without adaptation, damages will increase with
successively higher levels of global warming - Critical thresholds occurring at low levels of
global warming and sea level rise are much more
likely to be exceeded than those occurring at
higher levels
11Bleaching thresholds
12Simulated historical bleaching events at Magnetic
Island
13Mortality threshold
14Bleaching severity
15Bleaching risk as a function of warming
16When is the coping range of coral reef
communities exceeded?
- Physical bleaching rates
- Ecosystem damage
- Peoples livelihoods affected (e.g. fishing,
tourism) - Policy objectives
- Species/ecosystem rights to exist
- Are we happy with algal mats and seaweed?
17Bioclimatic thresholds exceeded as a function of
warming
18Macquarie River Catchment
- Area 75,000 km2
- P 1000 to lt400 mm.
- Major dams Burrendong and Windamere
- Water demands irrigation agriculture Macquarie
Marshes town supply - Most flow from upper catchment runoff
- Most demand in the lower catchment
19Irrigation allocations and wetland inflows-
historical climate and 1996 rules
20Critical thresholdsMacquarie River Catchment
- Irrigation
- 5 consecutive years below 50 allocation of water
right - Wetlands
- 10 consecutive years below bird breeding events
- Both thresholds are exceeded if mean streamflow
decreases - by 10 under a drought-dominated climate,
- by 20 under a normal climate and
- by 30 under a flood-dominated climate
21Risk analysis resultsMacquarie 2030
22Change in risk as a function of global warming
23Metrics for measuring costs
- Monetary losses (gains)
- Loss of life
- Change in quality of life
- Species and habitat loss
- Distributional equity
24Estimating dangerous climate change
- Assumptions
- Atmospheric CO2 3541500 ppm
- Climate sensitivity 1.54.5C
- Non-CO2 forcing 0.53.5Wm-2
- Randomly sampled at uniform distribution
25Temperature at stabilisation
26Temperature at stabilisation
27Probabilities of meeting temperature targets at
given levels of CO2 stabilisation
28Estimating dangerous climate change - Take 2
- Assumptions
- Atmospheric CO2 3541000 ppm (uniform)
- Climate sensitivity Expert (Forrest et al. non
linear) - Non-CO2 forcing 0.53.5Wm-2 , linked to CO2 (non
linear) - Randomly sampled
29Temperature at stabilisation
30Temperature at stabilisation
31Adaptation and mitigation
- Adaptation increases the coping range through
biological and social means - Mitigation reduces the magnitude and frequency of
greenhouse-related climate hazards - Therefore, they are complementary, not
interchangeable. - They also reduce different areas of climate
uncertainty
32Moving forward
- Adaptation
- Most suited to impacts vulnerable to current
climate risks or small changes in climate change
(These are the most likely to be affected) - Cannot cope with large changes or many impacts
(too expensive and difficult) - Adaptation will be local and mainly shorter-term
adjustments
- Mitigation
- Reduces climate hazards (e.g. global warming)
progressively from the top down. - Unlikely to prevent a certain level of climate
change adaptation will be needed for such
changes. - Mitigation that presents as a cost now will
become profitable when damages become more
apparent and BAU for the energy system changes to
low emission operation
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34Activities most at risk
- Those where
- critical thresholds are exceeded at low levels of
global warming, - adaptive capacity is low and/or adaptation is
prohibitively expensive, difficult or unknown and
- the consequences of exceeding those thresholds
are judged to be serious