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Warming Climate‐Induced Changes in Cloud Vertical Distribution Possibly Exacerbate Intra‐Atmospheric Heating Over the Tibetan Plateau

Yang Zhao, Jiming Li, Yifei Wang, Weiyuan Zhang, Deyu Wen

2024Geophysical Research Letters28 citationsDOIOpen Access PDF

Abstract

Abstract The complex and diverse cloud vertical distribution (CVD) largely impacts radiative and precipitation properties of clouds. Using 10‐year active satellite observations, we classified CVD over the Tibetan Plateau into 12 categories and found that overlapping clouds have less frequency but stronger radiative effect, heating rate and larger precipitation (partly reflecting the seeding effect) compared with single‐layer non‐strong convective clouds. Under a warming climate due to uniform sea surface temperature increase of 4K (quadrupling CO 2 increase), extremely high (>10 km) ice clouds will increase, particularly those below the tropopause will increase slightly (largely), accompanied by clear (weak) increases in stratospheric clouds. Simultaneously, a moderate to rapid decrease will occur in clouds below 10 km. Such CVD changes could further exacerbate tropopause warming. The probability of cloud overlap is also likely to increase in warmer climates, thus possibly further causing non‐convective cloud systems with stronger intra‐atmospheric heating, larger precipitation intensity and proportion.

Topics & Concepts

TropopauseAtmospheric sciencesEnvironmental sciencePlateau (mathematics)PrecipitationClimatologyRadiative transferGlobal warmingConvectionRadiative coolingClimate changeClimate modelTroposphereMeteorologyGeologyGeographyQuantum mechanicsMathematical analysisPhysicsOceanographyMathematicsAtmospheric aerosols and cloudsAtmospheric chemistry and aerosolsAtmospheric Ozone and Climate
Warming Climate‐Induced Changes in Cloud Vertical Distribution Possibly Exacerbate Intra‐Atmospheric Heating Over the Tibetan Plateau | Litcius