Sensitivity of precipitation extremes to ENSO variability

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Presentation transcript:

Sensitivity of precipitation extremes to ENSO variability ENSO provides a test-bed for analysing sensitivity of precipitation extremes to temperature change 1 day average 5 day average Change in Precipitation Intensity per oC warming (%/day) Increase of ~15% per oC warming 10 mm/day 20 mm/day 0 mm/day 4 mm/day Precipitation intensity percentile (%) Liu & Allan (2012) JGR; see also O’Gorman (2012) Nature Geosci Richard Allan, University of Reading

ENSO variability in global energy & water cycles HEATING (Wm-2) PRECIP (%) MOISTURE (%) TEMPERATURE (K) HEATING (Wm-2) PRECIPITATION (%) MOISTURE (%) TEMPERATURE (K) Updated from Allan et al. (2014) Surveys of Geophys & Allan et al. (2014) GRL 2.8 1.8 0.8 -0.2 -1.2 -2.2 Earth’s energy imbalance (Wm-2) Richard Allan, Reading

ENSO variability in global energy & water cycles Updated from Allan et al. (2014) Surveys of Geophys & Allan et al. (2014) GRL Or a simpler plot 1.8 0.8 - 0.2 -1.2 -2.2 Earth’s energy imbalance (Wm-2)

ENSO-related precipitation changes over tropical land Interanual-decadal changes in continental rainfall dominated by: La Niña (more rain) & El Niño (less rain) ENSO MEI AMIP CMIP GPCP P anomaly over ocean (mm/day) Land and ocean rainfall anti-correlated on interannual/ ENSO time-scale (above) GISS AMIP volcano Liu, Allan, Huffman (2012) GRL Liu & Allan (2013) ERL

ENSO variability as an emergent constraint on precipitation extremes? Sensitivity of tropical 5-day precipitation extremes to ENSO-related temperature variability (x-axis) plotted against future land response (y-axis) Future response (RCP4.5) GPCP ENSO variability (AMIP) Plot by Chunlei Liu, based on data from Allan et al. (2014) Surv. Geophys See O’Gorman (2012) Nature Geosci

El Niño minus La Niña changes in energy fluxes TOA solar TOA net Surface NET energy rad+turb Changes in top of atmosphere LW and SW consistent with shifts in cloud due to ENSO. These compensate in the NET TOA fluxes for high/deep cloud but a residual signal is evident over the Pacific ITCZ (stronger cloud greenhouse effect dominates more reflected sunlight), the Pacific stratocumulus zones (more absorbed sunlight AND more downward LW). The surface energy flux looks quite different as there is a large heat flux out the east Pacific in El Nino and reduced horizontal transport by a weaker Walker circulation (presumably less negative energy flow from the cooler east to warmer west so therefore greater energy convergence in the warm pool). - TOA LW DOWN Plot by Chunlei Liu: 1985-2015 (Allan et al. (2014) GRL and Liu et al. (2015) JGR)

Trends 1988-2008 (W=atmos moisture, T=surface temperature, P=precip, t=time) Allan et al. (2014) Surv. Geophys

Using ENSO variability to evaluating sensitivity of precipitation extremes to warming Observed/simulated 5-day mean response ① More positve dP/dT for heavier percentiles ② More positive observed sensitivity over ocean ③ Negative land dP/dT as more rain during cold La Nina ④ Interannual dP/dT not good direct proxy for climate change, especially over land …but may be good global indicator of model diversity e.g. O’Gorman (2012) ② ① ③ dP/dT (%) Tropics 1998-2008 RCP4.5 2080-2099 minus 1985-2005 ④ amip amip 5-day means. More positve dP/dT for heavier percentiles (obs and models) Higher observed sensitivity than models over ocean, good agreement over land. Mostly negative dP/dT for all percentiles (apart from heaviest) over land. Partly due to less rainfall over land in El Nino when warmer tropical T Coupled models: similar picture over ocean. Smaller sensitivity for highest percentiles under climate change since global increases in P with warming are muted by increasing CO2 levels. ④ Historical 1985-2005 Allan et al. (2014) Surv. Geophys

Tropical precipitation variability in satellite data and CMIP5 simulations Note consistency between atmosphere-only AMIP model simulations over land and GPCP observations. This is not the case for the ocean, in particular before about 1996. AMIP5 simulations with prescribed observed sea surface temperature can simulate GPCP observed rainfall variability over land. Oceans Land Tropical Land La Niña Volcano El Niño Liu, Allan, Huffman (2012) GRL