Tropical temperature distributions over a wide range of climates: theory and idealized simulations (2505.05912v1)

Abstract: Understanding future changes in temperature variability and extremes is an important scientific challenge with societal impacts. Here the responses of daily near-surface temperature distributions to climate warming is explored using an idealized GCM. Simulations of a wide range of climate states are performed using both a slab-ocean aquaplanet configuration and a simple continental configuration with a bucket-style model for land hydrology. In the tropics, the responses of extreme temperatures to climate change contrast strongly over land and ocean. Over land, warming is amplified for hot days relative to the average summer day. But over ocean, warming is suppressed for hot days, implying a narrowing of the temperature distribution. Previous studies have developed theories based on convective coupling to interpret changes in extreme temperatures over land. Building on that work, the contrasting temperature distribution responses over land and ocean are investigated using a novel theoretical framework based on local convective coupling. The theory highlights five physical mechanisms with the potential to drive differential warming across temperature percentiles: free-tropospheric temperature change, relative humidity change, convective available potential energy (CAPE) change, the hot-get-hotter mechanism, and the drier-get-hotter mechanism. Hot days are relatively dry over land due to limited moisture availability, which drives the drier-get-hotter mechanism and amplified warming of the warm tail of the distribution. This mechanism is the primary factor explaining the contrasting responses of hot days over land and ocean to climate change. But other mechanisms also contribute to changing the temperature distribution, with changes in free-tropospheric temperature and surface relative humidity having large influences (which partially cancel).