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Shortwave and longwave contributions to global warming under increased CO 2 Aaron Donohoe, University of Washington CLIVAR CONCEPT HEAT Meeting Exeter,

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Presentation on theme: "Shortwave and longwave contributions to global warming under increased CO 2 Aaron Donohoe, University of Washington CLIVAR CONCEPT HEAT Meeting Exeter,"— Presentation transcript:

1 Shortwave and longwave contributions to global warming under increased CO 2 Aaron Donohoe, University of Washington CLIVAR CONCEPT HEAT Meeting Exeter, September 30, 2015

2 Energy imbalance and temperature change ASR = OLR Unperturbed Atmospheric Emission Level Solar Perturbation ASR > OLR ASR = OLR Greenhouse Perturbation ASR > OLR ASR = OLR CO 2

3 Top of Atmosphere Radiative response to greenhouse and shortwave forcing OLR returns to unperturbed value in 20 years

4 Proposed solution – Positive SW feedback Absorbed Solar Radiation Outgoing Longwave Radiation Atmospheric Emission Level ASR > OLR Unperturbed ADD CO 2

5 Proposed solution – Positive SW feedback Absorbed Solar Radiation Outgoing Longwave Radiation Atmospheric Emission Level CO 2 + Warming OLR Increases WARMING ASR Increases + Feedback

6 Proposed solution – Positive SW feedback Absorbed Solar Radiation Outgoing Longwave Radiation Atmospheric Emission Level OLR = Unperturbed Energy still accumulating WARMING

7 Proposed solution – Positive SW feedback Absorbed Solar Radiation Outgoing Longwave Radiation Atmospheric Emission Level New Equilibrium OLR = ASR BOTH INCRESED WARMING

8 Inter-model spread in TOA response The TOA response to greenhouse forcing differs a lot between GCMs OLR returns to unperturbed values (Τ CROSS ) within 5 years for some GCMs and not at all for others (bi-modal) On average, Τ CROSS = 19 years Ensemble mean

9 Linear Feedback model C = heat capacity of climate system. Time dependent – meters of ocean T S = Global mean surface temperature change F SW and F LW are the SW and LW radiative forcing (including fast cloud response to radiative forcing – W m -2 ) λ LW and λ SW are the LW and SW feedback parameters. W m -2 K -1 Given above parameters and T S, we can predict the TOA response Energy Change ForcingFeedbacks Top of atmosphere (TOA) radiation

10 Backing out Forcing and feedbacks from instantaneous 4XCO2 increase runs Feedbacks parameters (λ LW and λ SW ) are the slope of –OLR and ASR vs. T S (W m -2 K -1 ) Forcing (F SW and F LW ) is the intercept (W m -2 ). Includes rapid cloud response to CO 2 (Gregory and Webb) CNRM model

11 Linear Feedback model works The TOA response in each model (and ensemble average) – solid lines– is well replicated by the linear feedback model What parameters (forcing, feedbacks, heat capacity) set the mean radiative response and its variations across models?

12 Ensemble average OLR recovery timescale λ LW = -1.7 W m -2 K -1 λ SW = +0.6 W m -2 K -1 F LW = + 6.1 W m -2 ASR in new equilibrium = T EQ λ SW = 4 W m -2 To come to equilibrium, OLR must go from - F LW = - 6.1 W m -2 to T EQ λ LW = +4 W m -2 OLR must change by 10 W m -2 to come to equilibrium  OLR crosses zero about 60% of the way the equilibrium Ensemble average forcing and feedbacks equilibrium temperature change OLR at time = 0 OLR at equilibrium

13 Climate model differences in OLR response time CNRM model

14 Sensitivity of τ CROSS to feedback parameters If F SW = 0 (simplification): τ CROSS = τ ln(-λ LW / λ SW ) Ensemble Average τ cross is determined by the OLR value demanded in the new equilibrium  Set by relative magnitudes of λ LW and λ SW  HAS STEEP GRADIENTS IN VICINITY OF λ SW =0

15 Cause of SW positive feedbacks: SW Water vapor feedback = +0.3±0.1 W m -2 K -1 Surface albedo feedback = +0.26 ±0.08 W m -2 K -1 Bony et al. (2006) ocean ice absorbed incident H 2 0 (vapor) Reflected cloud transmitted Reflected surface

16 Observations of the co- variability of global mean surface temperature and ASR/OLR give statistically significant estimates of λ SW and λ LW λ SW = 0.8 ± 0.4 W m -2 K -1 λ LW = -2.0 ± 0.3 W m -2 K -1

17 Implications for OLR recovery timescale Observational constraints suggest that τ cross is of order decades IN RESPONSE TO LW FORCING ONLY Assumes an (CMIP5 ensemble average) radiative relaxation timescale (τ) of 27 years τ CROSS = τ ln(-λ LW / λ SW )

18 Can we get climate feedbacks from interannual variability of CERES (and surface temperature)?

19 Radiation causes surface temperature anomalies as well as responds to it– potential to confuse the non- feedback forcing with the feedback.

20 Conclusions CO2 initiates global warming by decreasing OLR but the TOA energy imbalance is dominated by increased absorbed solar radiation in most climate models – associated with surface albedo and SW water vapor feedbacks CERES data also suggest a positive shortwave feedback  global warming will most likely result in enhanced ASR and we should not expect to see reduced OLR from the forcing Can interannual variability in CERES tell us anything about climate feedbacks?

21 How to reconcile this – response to greenhouse forcing with a shortwave feedback Greenhouse forcing F LW = 4 W m -2 LW feedback only Forcing = response F LW = -λ LW ΔT ΔT= 2K ΔT = F LW /-λ LW = 2 K if λ LW = -2 W m -2 K -1 -λ LW ΔT = 4 W m -2 F LW = 4 W m -2 LW and SW feedback Forcing = response F LW = -(λ LW +λ SW ) ΔT ΔT = F LW /-(λ LW + λ SW ) = 4 K if λ SW = +1 W m -2 K -1 λ LW ΔT = 8 W m -2 ΔT= 4K λ SW ΔT = 4 W m -2 ΔOLR = 0 ΔOLR= -F LW + -λ LW ΔT = ΔASR

22 Time evolution of OLR response to greenhouse forcing with SW feedback OLR ASR F LW OLR must go from –FLW at time 0 to FLW in the equilibrium response  OLR returns to unperturbed value when half of the equilibrium temperature change occurs The energy imbalance equation: Has the solution:

23

24 Are the radiative feedbacks that operate on inter-annual timescales equivalent to equilibrium feedbacks? SW LW NET

25 Water Vapor as a SW Absorber (Figure: Robert Rhode Global Warming Art Project)

26 Heat capacity: 4XCO 2 Heat capacity increases with time as energy penetrates into the ocean In first couple decades, energy is within the first couple 100 m of ocean and system e-folds to radiative equilibrium in about a decade

27 How fast does the system approach equilibrium? C = 250 m (30 W m -2 year K -1 ) the ensemble average for first century after forcing λ LW = -1.7 W m -2 K -1 λ SW = +0.6 W m -2 K -1 Ensemble average forcing and feedbacks The energy imbalance equation: Has the solution: Key point: OLR returns to unperturbed value in of order the radiative relaxation timescale of the system  decades

28 What parameter controls inter- GCM spread in TOA response? Using all GCM specific parameters gets the inter-model spread in τ cross Varying just λ SW and F SW between GCMS captures inter-model spread in τ cross λ LW, F LW and heat capacity differences between GCMs less important for determining the radiative response Varying just λ SW gives bi-modal distribution of τ cross with exception of two models (F SW plays a role here)

29 τ cross dependence on feedback parameters λ LW = -1.7 W m -2 K -1 λ SW = +0.6 W m -2 K -1 F LW = + 6.1 W m -2 equilibrium temperature change Ensemble average forcing and feedbacks OLR =0 at τ=τ cross initial final transition How far from equilibrium OLR =0

30 How fast does the system approach equilibrium? C = 250 m (30 W m -2 year K -1 ) the ensemble average for first century after forcing λ LW = -1.7 W m -2 K -1 λ SW = +0.6 W m -2 K -1 Ensemble average forcing and feedbacks The energy imbalance equation: Has the solution: Key point: OLR returns to unperturbed value in of order the radiative relaxation timescale of the system  decades

31 What parameter controls inter- GCM spread in TOA response? Using all GCM specific parameters gets the inter-model spread in τ cross Varying just λ SW and F SW between GCMS captures inter-model spread in τ cross λ LW, F LW and heat capacity differences between GCMs less important for determining the radiative response Varying just λ SW gives bi-modal distribution of τ cross with exception of two models (F SW plays a role here)

32 τ cross dependence on feedback parameters λ LW = -1.7 W m -2 K -1 λ SW = +0.6 W m -2 K -1 F LW = + 6.1 W m -2 equilibrium temperature change Ensemble average forcing and feedbacks OLR =0 at τ=τ cross initial final transition How far from equilibrium OLR =0

33 Sensitivity of τ CROSS to feedback parameters If F SW = 0 (simplification): Ensemble Average τ cross is determined by the OLR value demanded in the new equilibrium  Set by relative magnitudes of λ LW and λ SW  HAS STEEP GRADIENTS IN VICINITY OF λ SW =0

34 What parameter controls inter- GCM spread in TOA response? While the relative magnitudes of λ SW and λ LW explain the vast majority of the spread in τ cross there are several model outliers A more complete analysis includes inter-model differences in F SW  F SW includes both direct radiative forcing by CO2 (small) and the rapid response of clouds to the forcing

35 From before, if F SW =0 then::If F SW ≠ 0 then:: Forcing Gain = 2 If |λ SW | = ½ |λ LW |  T EQ is doubled The OLR change to get to equilibrium is: (2*F LW / |λ LW |) * |λ LW | = 2F LW  OLR = 0 occurs half way to equilibrium  T CROSS = T ln(2) If F LW = F SW  T EQ is doubled and OLR asymptotes to +F LW  OLR = 0 occurs half way to equilibrium  T CROSS = T ln(2) Feedback Gain = 2

36 SW and LW Feedbacks and Forcing: 4XCO 2 LW SW Ensembl e Average Feedbacks Forcing LW feedback is negative (stabilizing) and has small inter- GCM spread SW feedback is mostly positive and has large inter-GCM spread Forcing is mostly in LW (greenhouse) SW forcing has a significant inter-GCM spread

37 Sensitivity of τ CROSS to feedback parameters Positive SW forcing and feedbacks favor a short OLR recovery timescale with a symetric dependence on the “gain” factors Explains the majority (R= 0.88) of inter- model spread Assumes a time and model invariant heat capacity (250m ocean depth equivalent)

38 LW Feedback parameter from observations Surface temperature explains a small fraction of OLR’ variance (R=0.52) Error bars on regression coefficient (1σ) are small, why? Weak 1 month auto-correlation in OLR’ – r OLR (1month) = 0.3  lots of DOF (N*= 113) Even if none of the OLR’ variance was explained, the regression slope is still significant  Given the number of realizations, you would seldom realize such a large regression coefficient in a random sample – in the absence of a genuine relationship between T S and OLR Unexplained amplitude Independent realizations

39 SW Feedback parameter from observations Very weak correlation (r=0.16) Almost no memory in ASR’ – r OLR (1month) = 0.1 – mean we have lots of DOF (N*= 143) The significance of the regression slope is not a consequence of the variance explained but, rather, the non-zero of the slope despite the number of realizations  The feedback has emerged from the non-feedback radiative processes in the record

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