Litcius/Paper detail

The Influence of Cloud Types on Cloud‐Radiative Forcing During DYNAMO/AMIE

Hrag Najarian, Naoko Sakaeda

2023Journal of Geophysical Research Atmospheres11 citationsDOIOpen Access PDF

Abstract

Abstract Cloud‐radiative feedback is known to be an important process for the Madden‐Julian Oscillation (MJO) and its accurate representation in general circulation models. The MJO is known to have a stronger cloud‐radiative feedback compared to higher frequency convectively coupled equatorial waves (CCEW), for reasons that remain unclear. The objective of this study is to use data from the Dynamics of the MJO/Atmospheric Radiation Measurement MJO Investigation Experiment field campaign to investigate how cloud type evolution and their associated cloud‐radiative forcing (CRF) differ between the MJO and CCEWs and their application to MJO dynamics under moisture mode theory. This study finds that the amplitude of CRF is the largest within the MJO compared to the higher frequency CCEWs, and CRF maximizes after the maximum precipitation (enhanced phase) of the MJO. We suggest this delay in the timing of maximum CRF occurs because most cloud types (congestus, deep, anvil, and cirrus) simultaneously maximize in frequency after the enhanced phase of the MJO, which is not seen for the higher frequency CCEWs. These specific cloud types help maintain the MJO through their radiatively‐driven moistening which acts to prolong the enhanced phase of the MJO. The decomposition of radiatively‐driven moistening by cloud types shows that simultaneous moistening by deep, anvil, and congestus clouds are particularly responsible for the maintenance of the MJO under moisture mode theory. This analysis suggests the importance of capturing the correct evolution of different cloud types and their associated radiative effects to better understand the thermodynamics of the MJO.

Topics & Concepts

Madden–Julian oscillationRadiative transferClimatologyDynamoPrecipitationForcing (mathematics)Cloud forcingAtmospheric sciencesCloud computingEnvironmental scienceRadiative forcingMeteorologyConvectionPhysicsGeologyComputer scienceAerosolQuantum mechanicsOperating systemMagnetic fieldClimate variability and modelsMeteorological Phenomena and SimulationsTropical and Extratropical Cyclones Research