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CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner Climate Dynamics of Tropical Africa: Capturing Paleoclimate.

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Presentation on theme: "CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner Climate Dynamics of Tropical Africa: Capturing Paleoclimate."— Presentation transcript:

1 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu Climate Dynamics of Tropical Africa: Capturing Paleoclimate Changes Bette Otto-Bliesner National Center for Atmospheric Research, Boulder, Colorado Zhang et al., GMD, 2012

2 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu The Sahel Since 1950, the Sahel has seen persistent anomalies of precipitation: 1950s – 1960s, persistent excessive rainfall 1970s – 1980s, excessive drought Partial recovery, rise in extreme events Satellite observations indicate a strong increase in seasonal greenness since the early 1980s. Proposed cause are numerous, including: Improved agricultural practices Increasing GHGs, direct and indirect (SST) effects on Sahel rainfall.

3 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu Past and Future − Data and Models

4 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu Data − Glacial-Interglacial Measurements: siliciclastic grain size variations in a deep-sea core off western Africa and alkenone measurements from two sediment cores near Portuguese margin Interpretation: African “humidity index” displays eccentricity-modulated precessional cycles (~20 kyr), with millennial variations correlated with North Atlantic SSTs deMenocal, Science, 2008

5 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu Models − Glacial-Interglacial: Orbital Forcing CLIMBER2 AOV Model Simulation Interpretation: Recurrence of humid periods when precession-forced orbital monsoon forcing is strong. Greening of Sahel and Sahara associated with precipitation increases. Tjallingii et al., Science, 2008 Sahara box Sahel box Wet Dry

6 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu Models − Glacial-Interglacial: Millennial Events Measurements: grain size and elemental ratios in marine core GeoB9508-5, on continental slope just west of Senegal River mouth. Interpretation: Data: Strong decreases in Al/Si and Fe/K ratios during Heinrich stadials are associated with much lower sediment discharge from Senegal River  arid West African Sahel. Mulitza et al., Paleoceanography, 2008 CCSM2 AO “Hosing” Simulation P-E (m/yr) Climate model: Cold North Atlantic during meltwater events induces a southward shift of West African monsoon trough and mid- tropospheric African Easterly Jet. LGMHolocene AHP

7 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu Last 21ka – Deglaciation and Holocene deMenocal et al., 2000; Gasse, 2000; Tierney et al. 2008 Abrupt, synchronous initiation of the African Humid Period across Africa? The DATA Street-Perrott & Perrott, 1993 African Humid Period

8 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu Role of Climate Forcings TraCE (Transient Climate Evolution) Project to simulate 21ka to present Community Climate System Model 3 Atmosphere model, 3.75° lat-lon Land model with predicted vegetation Ocean model, ~3°, 25 levels Sea ice model, dynamic & thermodynamic Otto-Bliesner et al., Science, 2014 20°N JJA 10°S DJF NH meltwaterSH meltwater AHP Ice sheets: ICE-5G Three simulations TraCE – all forcings: GHG, orbital, ice sheets, and meltwater TraCE – orbital-only* TraCE – GHG-only* * All else held at 17ka

9 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu 21 ka 10 ka TLAI Δ SST TraCE simulation Proxy data TraCE simulation versus Proxy Data Otto-Bliesner et al., Science, 2014 Data and TraCE simulation Relatively dry at LGM (~20ka) Even drier from ~18 to 15ka Abrupt increase in moisture at ~14.7ka AHP Atlantic ocean overturning circulation

10 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu 21 ka 10 ka TLAI Δ SST Dominant Pattern of Hydroclimate Variability Otto-Bliesner et al., Science, 2014 Pan-African coherent changes Dry from LGM (20ka) to 17ka Increase in moisture from 17ka to 11ka Some drying at Younger Dryas period (~12ka)

11 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu 21 ka TLAI Δ SST Sensitivity to GHG and Orbital Forcings Deglacial change (11ka minus 17ka) of model precipitation Otto-Bliesner et al., Science, 2014 Monsoon nature of rainfall: North Africa – NH summer months SE equatorial Africa – SH summer months TraCE simulation with all forcings shows summer rainfall increases from 17ka to 11ka in both regions. Only orbital forcing: Sahel: Increased summer rainfall plus northward expansion. SE equatorial Africa: Decreased summer rainfall. Only GHG forcing: Sahel: Increased summer rainfall. SE equatorial Africa: Increased summer rainfall.

12 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu 21 ka 10 ka TLAI Δ SST Sensitivity to GHG and Orbital Forcings Otto-Bliesner et al., Science, 2014 Annual TraCE – all forcings GHG only Orbital only

13 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu 21 ka 10 ka Δ SST Meltwater and North Atlantic Influence Otto-Bliesner et al., Science, 2014 Meltwater to North Atlantic Slowdown of thermohaline circulation

14 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu 21 ka 10 ka TLAI Δ SST Meltwater and North Atlantic Influence LGM to Heinrich 1 change (17ka minus 20ka) Adding meltwater to the North Atlantic, cooling the SSTs, and slowing the ocean conveyor circulation, With the ocean transporting less heat northward, the South Atlantic warms, Shifting rainfall south, drying North Africa. Ocean circulation takes too long to transmit to SE equatorial Africa, Instead the cooling is transmitted westward over Europe, then southward over the Indian Ocean by the atmosphere, Shifting rainfall south, drying SE equatorial Africa. When meltwater to North Atlantic ceases, rainfall pattern abruptly flips back

15 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu A Challenge: Green Sahara during the AHP 21 ka 10 ka TLAI Δ SST Poorly-represented positive land- atmosphere feedbacks?  Vegetation (As opposed to desert) influences surface albedo, evapotranspiration.  Soil Composition and color affect soil albedo and soil water retention.  Groundwater hydrology Groundwater for recharging large lakes in mid- Holocene accumulated during Early Holocene.  Dust More vegetated land surface with greater soil moisture and enlarged lakes −> decreased dust production. IPCC AR5 WG1 report, Chapter 9, 2013

16 CSDMS Annual Meeting 2016: Capturing Climate Change May 2016 Bette Otto-Bliesner ottobli@ucar.edu 21 ka 10 ka TLAI Δ SST GHG changes, particularly atmospheric CO 2, played an important role in the pan-African rainfall response during the deglaciation, Onset of African Humid Period synchronized by state of Atlantic Meridional Overturning Circulation. Concluding Remarks IPCC AR5 WGI, 2013 Precipitation scaled by global temperature (% per °C)

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