| Abstrakt: |
We compare abrupt CO2‐quadrupling (abrupt‐4xCO2) and ‐doubling (abrupt‐2xCO2) simulations across 10 CMIP6 models. Two models (CESM2 and MRI‐ESM2‐0) warm substantially more than twice as much under abrupt‐4xCO2 than abrupt‐2xCO2, which cannot be explained by the non‐logarithmic scaling of CO2forcing. Using an energy balance model, we show that increased warming rates within these two models are driven by both less‐negative radiative feedbacks and smaller global effective heat capacity under abrupt‐4xCO2. These differences are caused by a decrease in low cloud cover andshallower ocean heat storage, respectively; both are linked to smaller fractional declines in the Atlantic Meridional Overturning Circulation (AMOC) under abrupt‐4xCO2 (relative to abrupt‐2xCO2). On a global scale, higher climate sensitivity under larger forcing can be explained by a feedback‐temperature dependence; however, we find that forcing‐dependent spatial warming patterns due to AMOC decline are an important physical mechanism which reduces warming in a way that is not captured by a global‐mean framework. Climate model simulations with abruptly quadrupled CO2concentrations are often used to characterize the climate response of global climate models to greenhouse gas forcing and inform predictions of the future. In this study, we ask how relevant CO2‐quadrupling experiments are to more modest warming scenarios by comparing them to CO2‐doubling experiments. It is usually assumed that CO2‐quadrupling will produce about twice as much warming than CO2‐doubling, but this is not the case in some models. Two global climate models in particular warm much more under CO2‐quadrupling than twice the warming under CO2‐doubling. By fitting each climate model to a simpler energy balance model, we find that these two climate models are strongly impacted by the effective heat capacity (which can be impacted by ocean circulation changes) in comparison to other climate models where radiative effects (such as effects from clouds) are more impactful. Changes in the strength of an Atlantic Ocean circulation are important for both radiative effects and heat storage. Therefore, the behavior of our planet at 1.5 or 2 times CO2cannot necessarily be estimated with quadrupling CO2experiments. Models with disproportionate Atlantic Meridional Overturning Circulation (AMOC) declines under abrupt CO2doubling experience less warmingAMOC decline modulates transient warming by influencing bothlow cloud feedbacks and the global effective heat capacityTherefore, abrupt quadrupling of pre‐industrial CO2simulations do not necessarily capture the behavior of lesser warming scenarios Models with disproportionate Atlantic Meridional Overturning Circulation (AMOC) declines under abrupt CO2doubling experience less warming AMOC decline modulates transient warming by influencing bothlow cloud feedbacks and the global effective heat capacity Therefore, abrupt quadrupling of pre‐industrial CO2simulations do not necessarily capture the behavior of lesser warming scenarios |
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