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Climate Sensitivity & Climate Feedback Instructor: Prof. Johnny Luo http://www.sci.ccny.cuny.edu/~luo Te 4 4 (S0 /4)(1 ) (1367/4)(1 0.3) 5.67 108 255K 180 C Te 4 4 (S0 /4)(1 ) (1367/4)(1 0.3) 5.67 108 255K 180 C Considering the Greenhouse Effect Ts = 15 0C > -18 0C EAS 488/B8800 Climate & Climate Change Part I: Fundamentals of Climate Science 1.Introduction to the climate system 2.The Earth’s energy balance 3.Atmospheric radiation and climate 4.Surface energy balance 5.Atmosphere general circulation 6.Ocean general circulation Energy budget (global balance & local imbalance) Fluid movement (due to local energy imbalance) Part II: Climate Change 1.Climate sensitivity & climate feedback 2.Natural & anthropogenic climate change 3.IPCC assessment of past & future climate change What will happen if energy imbalance occurs at a global level? Outlines 1. Basic concepts: climate forcing, response, sensitivity and feedbacks 2. Climate sensitivity w/o feedback 3. Water vapor feedback 4. Ice albedo feedback 5. Cloud feedback 6. Tropical SST regulatory mechanism 7. Daisy world Global energy balance: the starting point This chapter deals with: S0 (1 ) Te 4 4 1) what may break this balance? 2) what will happen when this balance is violated? First, we will look at a few fundamental concepts: 1) 2) 3) 4) climate forcing, climate response, climate sensitivity climate feedback Forcing & Response Climate Forcing: change in external factors that breaks the aforementioned energy balance (usually measured in changes in energy flux density in W m-2 at TOA). Climate Response: adjustment of the climate system in response to the external forcings (usually measured as change in surface temperature, Ts). Climate Sensitivity: climate response (Ts) over climate forcing (Q). dTs dQ Example: Q S0 (1 ) T 4 4 Forcing: When CO2 is doubled, OLR will change from 240 W m-2 to 236 W m-2 (is this a warming or cooling for the climate system?). Response: For planet A: Ts increases by 1 K; for planet B: Ts increases by 10 K. Sensitivity: λ(A) = 1K/(4 W m -2) = 0.25 K/(W m -2). λ(B) = 10K/(4 W m -2) = 2.5 K/(W m -2). Outlines 1. Basic concepts: climate forcing, response, sensitivity and feedbacks 2. Climate sensitivity w/o feedback 3. Water vapor feedback 4. Ice albedo feedback 5. Cloud feedback 6. Tropical SST regulatory mechanism 7. Daisy world Sensitivity of the Earth’s climate RTOA S0 (1 ) Te 4 0 4 equilibrium Suppose a forcing dQ is imposed on RTOA. Let’s calculate the climate sensitivity dTs/dQ. RTOA RTOA (Q,Ts (Q)) dRTOA RTOA RTOA dTs 0 dQ Q Ts dQ =1 New equilibrium: RTOA = 0 dTs 1 dQ RTOA /Ts Sensitivity parameter Sensitivity of the Earth’s climate RTOA S0 (1 ) Te 4 0 4 equilibrium Suppose a forcing dQ is imposed on RTOA. Let’s calculate the climate sensitivity dTs/dQ. dQ: forcing; dTs: response RTOA RTOA (Q,Ts (Q)) Sensitivity of the Earth’s climate RTOA S0 (1 ) Te 4 0 4 equilibrium Suppose a forcing dQ is imposed on RTOA. Let’s calculate the climate sensitivity dTs/dQ. dQ: forcing; dTs: response RTOA RTOA (Q,Ts (Q)) dRTOA RTOA RTOA dTs 0 dQ Q Ts dQ = 1 (b/c instantaneous changes in RTOA & dQ are the same) New equilibrium at the TOA Sensitivity of the Earth’s climate RTOA S0 (1 ) Te 4 0 4 equilibrium Suppose a forcing dQ is imposed on RTOA. Let’s calculate the climate sensitivity dTs/dQ. dQ: forcing; dTs: response RTOA RTOA (Q,Ts (Q)) dRTOA RTOA RTOA dTs 0 dQ Q Ts dQ = 1 (b/c instantaneous changes in RTOA & dQ are the same) New equilibrium at the TOA dTs 1 dQ RTOA /Ts Sensitivity parameter Now we calculate: RTOA /Ts S0 (1 ) Te4 4 RTOA (Te4 ) 4Te3 Ts Ts RTOA Assuming: 1) solar constant is unchanging, and 2) Te and Ts change at the same rate Now we calculate: RTOA /Ts S0 (1 ) Te4 4 RTOA (Te4 ) 4Te3 Ts Ts RTOA Assuming: 1) solar constant is unchanging, and 2) Te and Ts change at the same rate Estimating the sensitivity parameter (Te = 255 K for current climate) dTs 1 1 2 1 0.26 K(W m ) 3 dQ RTOA /Ts 4Te What this means is: for every 1 W m-2 of energy we add to or subtract from the climate system, change of effective temperature (or surface temperature) will be 0.26 K. This is dictated by the Stefan-Boltzmann relation. Note that other factors (e.g., albedo, water vapor) are held unchanged at this point. dTs 0.26 K(W m 2 )1 dQ This is the climate sensitivity that is built-in of the σTe4 relationship. Think-Pair-Share Questions: 1)For this kind of climate system, i.e., λ=0.26 K (W m-2)-1, what dQ is needed to warm up the Earth’s surface by 1K (i.e., dTs=1K) ? 2)How many W m-2 does the Solar Constant (S) have to increase to achieve dTs=1 K? Assume the albedo is 0.3 RTOA S0 4 (1 ) Te 4 Think-Pair-Share Questions: 1)For this kind of climate system, i.e., λ=0.26 K (W m-2)-1, what dQ is needed to warm up the Earth’s surface by 1K (i.e., dTs=1K) ? 2)How many W m-2 does the Solar Constant (S) have to increase to achieve dTs=1 K? Assume the albedo is 0.3 1 W m-2 -> 0.26 K about 4 W m-2 is needed for 1 K. To achieve 4 W m-2 thru changing the Solar Constant (S0) S0 (1 ) 4 S0 (1 0.3) 4 W m2 S0 22 W m2 4 S0 1370 W m2 Observations show that S0 varies in magnitude of 1 W m2 (historical data dated back to 1870 can also support this estimate; however, over a longer history such as millions of years, there are larger variations). dTs 0.26 K(W m 2 )1 dQ Conclusion: the σTe4 type of climate system is a rather stable one because of the fundamental way energy balance is achieved. So, S0(1-0.3)/4 = 0.175 W m2. With this climate forcing, the response will be 0.175 × 0.26 = 0.0455 K. Outlines 1. Basic concepts: climate forcing, response, sensitivity and feedbacks 2. Climate sensitivity w/o feedback 3. Water vapor feedback 4. Ice albedo feedback 5. Cloud feedback 6. Tropical SST regulatory mechanism 7. Daisy world Feedback mechanism: Sensitivity = Output/Input. With feedback, the sensitivity parameter will be different. dTs 0.26 K(W m 2 )1 dQ T-P-S: How will water vapor affect the intrinsic climate sensitivity parameter? In other words, given the same forcing, how will water vapor changes the Ts response? Feedback mechanism: Water vapor: a strong positive feedback in global warming scenario dQ Increasing CO2 dTs Temperature H2O IR absorption spectra (0 means no absorption; 100 means total absorption) Much of the infrared absorption (greenhouse effect) comes from the contribution of H2O Clausius-Clapeyron relationship (C-C): saturation vapor pressure increases with temperature des L dT ( ) es Rv T T For current terrestrial conditions, for every 1 K increase in temperature, es increases by ~ 6%. Calculate OLR as a function of surface temperature (holding RH constant so vapor pressure increases with Ts). This will need a radiative transfer model. For each Ts, we calculate I (OLR), so we have dTs/d(OLR) OLR increases with increasing Ts, but at a SLOWER rate than what the stefan-Boltzmann relationship gives: σ(Ts30)4. Red: assume clear sky Green: average cloudiness T* is the surface temperature (Ts). T* - 10, T* - 20, …, T* - 50 are attempts to estimate the effective temperature (Te) from the surface temperature. For global average, T* = 288 K, Te = 255 K, so T* 30 is a good approximation for global average curve. Conclusion: because of the water vapor feedback, climate sensitivity is HIGHER than a sigma-Tto-the-4th relationship. dOLR 1 ( ) dTs With water feedback dTs 0.5 K(W m2 )1 dQ Ts Ts (Q,H 2O) dTs Ts Ts dH2O 0.5 K(Wm 2 )1 dQ Q H 2O dQ 0.26 K (Wm-2)-1 Climate sensitivity has doubled with water vapor feedback. Summary Sensitivity = response / forcing. Climate Forcing: change in external factors that breaks the energy balance of the climate system (usually measured in changes in energy flux density in W m-2 at TOA). RTOA S0 (1 ) T 4 0 4 Climate Response: adjustment of the climate system in response to the external forcings (usually measured as change in surface temperature, Ts). Climate sensitivity w/o feedback: dTs 1 1 2 1 3 0.26 K(W m ) dQ RTOA /Ts 4Te Double CO2 forcing: 4 W m-2 -> 4×0.26 ≈ 1 K Summary dTs dQ Feedback mechanism: dQ Increasing CO2 (or whatever causes the warming) dTs Temperature goes up H2O goes up dTs 1 0.5 K(W m 2 ) 1 dQ RTOA /Ts Water vapor: a strong positive feedback, doubling the climate sensitivity