monitoring climate change from space
DESCRIPTION
Monitoring Climate Change from Space. Richard Allan Department of Meteorology, University of Reading. Why Monitor Earth’s Climate from Space?. Global Spectrum Current Detection Understanding Prediction. The problem. IPCC: www.ipcc.ch/ipccreports/ar4-wg1.htm. - PowerPoint PPT PresentationTRANSCRIPT
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Monitoring Climate Change from Space
Richard AllanDepartment of Meteorology, University of Reading
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Why Monitor Earth’s Climate from Space?
• Global• Spectrum• Current• Detection• Understanding• Prediction
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The problem...
IPCC: www.ipcc.ch/ipccreports/ar4-wg1.htm
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Absorbed Solar or Shortwave Radiation (S/4)(1-α)
Thermal/Infra-red or Outgoing Longwave Radiation (OLR)=σTe
4
πr2S
Earth’s Radiation balance in space4πr2
• There is a balance between the absorbed sunlight and the thermal/longwave cooling of the planet:
(S/4)(1-α) ≈ σTe4
• How does it balance? Why is the Earth’s average temperature about 15oC? e.g. Lacis et al. (2010) Science
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Earth’s global annual average energy balance
240 Wm-2 240 Wm-2
390 Wm-2
Surface Temperature = +15oC
Solar Thermal
Efficiency ~61.5%
Radiating Efficiency, or the inverse of the Greenhouse Effect, is strongly determined by water vapour absorption across the electromagnetic spectrum
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Now double CO2 or reduce suns output: a “radiative forcing”
240 Wm-2 236 Wm-2
390 Wm-2
Surface Temperature = +15oC
Solar Thermal: less cooling to space
Efficiency ~60.5%
Radiative cooling to space through longwave emission drops by about 4 Wm-2 resulting in a radiative imbalance
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The climate system responds by warming
240 Wm-2 236 Wm-2
390 Wm-2
Surface Temperature = +15oC
Solar > Thermal
Efficiency ~60.5%Heating
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240 Wm-2 240 Wm-2
397 Wm-2
Surface Temperature = +16oC
Solar = Thermal
Efficiency ~60.5%
The 2xCO2 increased temperature by about 1oC in this simple example. So what’s to worry about?
The climate system responds by warming
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But it’s not that simple…
IPCC (2007)
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Climate forcing and feedback : a natural experiment
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29/3/06 11.05am
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29/3/06 12.26pm
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• Clouds affect radiation fluxes• Radiation fluxes affect clouds
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Temperature
Additional surface heating
Reduced reflection of suns rays
Melting ice and snow
CO2
Feedback loops or “vicious circles” amplify or diminish initial heating or cooling tendencies e.g. Ice “albedo” Feedback
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One of the strongest positive amplifying feedbacks involves gaseous water vapour
CO2
Greenhouse effect
Net Heating
Temperature
Water vapour
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Cloud Feedback: a complex problem
• Clouds cool the present climate
• Will clouds amplify or reduce future warming?
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Monitoring Climate From Space
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file:///C:/Documents%20and%20Settings/Richard%20Allan/My%20Documents/CONTED/ANIMATIONS/200603_60min_DUST.mov
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IRIS/IMG spectra: Harries et al. 2001, Nature
CO2 O3
CH4
Satellite measurements (1970, 1997) confirm the effect of increasing greenhouse gases
1/wavelengthSt
rong
er g
reen
hous
e e
ffect
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Monitoring Natural forcings: The Sun
See also: http://www.pmodwrc.ch/pmod.php?topic=tsi/composite/SolarConstant
0.1
0.2
0.0
Implied changes in global tem
peratureACRIM/VIRGO
Lean (2000) Y.Wang (2005)
IPCC WG1 2.7.1 (p.188-193)
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Monitoring Sea level
Coastal tide gaugesRecontructed (proxy)Satellite altimetry
IPCC 2007 Fig. 5.13 (p. 410)
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Current rises in global sea level
Research by Rahmstorf et al. (2007) Science, 4 May
Is sea level rising faster than projections made by numerical climate simulations?
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Monitoring sea surface
temperature
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Monitoring Land Ice From Space
Right: NASA's ICE-Sat satellite - Ice, Cloud and land Elevation Satellite
Above: results from Gravity Recovery And Climate Experiment (GRACE) mission
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NSIDC : http://nsidc.org/news
Arctic sea ice: recovery from 2007 minimum but robust downward trends in extent since 1979 measured by SSM/I satellite instruments
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Remote sensing clouds and aerosol Remote sensing clouds and aerosol from space: Cloudsat and CALIPSOfrom space: Cloudsat and CALIPSO
Cloudsat radar
CALIPSO lidar
Target classificationInsectsAerosolRainSupercooled liquid cloudWarm liquid cloudIce and supercooled liquidIceClearNo ice/rain but possibly liquidGround
Work by Dr. Julien Delanoë and Prof. Robin Hogan, University of Reading
• Radar: ~D6, detects large particles (e.g. ice)
• Lidar: ~D2, more sensitive to thin cirrus, low-level liquid clouds and aerosol pollutants but signal is attenuated
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How will the water cycle change?
Work by Dr. Ed Hawkins and Prof. Rowan Sutton, University of Reading
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Trenberth et al., work published in the Bulletin of the American Meteorological Society (2009) and Intergovernmental Panel on Climate Change (2007)
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Physical basis: water vapour
• Physics: Clausius-Clapeyron • Low-level water vapour concentrations increase with atmospheric
warming at about 7%/K – Wentz and Shabel (2000) Nature; Raval and Ramanathan (1989) Nature
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Extreme Precipitation
• Large-scale rainfall events fuelled by moisture convergence– e.g. Trenberth et al. (2003) BAMS
Intensification of rainfall (~7%/K?)
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Allen and Ingram (2002) Nature
Global Precipitation is constrained by energy balance
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Changing character of rainfall events
Pre
cipi
tatio
n
Heavy rain follows moisture (~7%/K)
Mean Precipitation linked to
radiation balance (~3%/K)
Light Precipitation (-?%/K)
Temperature
See discussion in Trenberth et al. (2003) Bulletin of the American Meteorological Society
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• Increased Precipitation• More Intense Rainfall• More droughts• Wet regions get wetter, dry
regions get drier?• Regional projections??
Precipitation Change (%)
Climate model projections (see IPCC 2007)
Precipitation Intensity
Dry Days
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Pre
cip.
(%
)
Allan and Soden (2008) Science
Using microwave measurements from satellite to monitor the water cycle
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The rich get richer…
Allan et al. (2010) Environmental Research Letters
Dry
Wet
Pre
cipi
tatio
n ch
ange
(%
)
ObservationsModels
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Conclusions
• Earth’s radiative energy balance drives climate change• It also provides a rich spectrum of information
Monitoring and detecting climate change Understanding physical processes Enabling and evaluating prediction
• Challenges... Clouds & Aerosol Precipitation Regional impacts
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Earth’s global average energy balance: no atmosphere
240 Wm-2 240 Wm-2
240 Wm-2
Surface Temperature = -18oC
Solar Thermal
Efficiency = 100%
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240 Wm-2
240 Wm-2
Temperatures rise
Solar > Thermal
Heating
Earth’s global average energy balance: add atmosphere
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Earth’s global average energy balance: present day
240 Wm-2 240 Wm-2
390 Wm-2
Surface Temperature = +15oC
Solar Thermal
Efficiency ~60%
The greenhouse effect helps to explain why our planet isn’t frozen. How does it work?
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