RT Journal Article
T1 Resolution dependence of tropical poleward energy transport in aquaplanet GCMs
A1 Chang, Chiung‐Yin
A1 Lin, Pu
A1 Held, Isaac M.
A1 Merlis, Timothy M.
A1 Zurita Gotor, Pablo
AB The tropical atmosphere plays an important role in transporting energy poleward and driving the global circulation. However, understanding and simulating this fundamental aspect of our climate remains difficult due to its sensitivity to convective parameterizations and horizontal resolution. This study focuses on benchmarking the resolution dependence of tropical poleward energy transport in two aquaplanet atmospheric general circulation models with disabled convective parameterizations: a nonhydrostatic high-resolution (100–6 km) finite-volume cubed-sphere model with a full physics package and a lower-resolution (300–100 km) hydrostatic spectral model with idealized moist physics. Despite differences in their physics and numerics, both models demonstrate that column-integrated poleward moist static energy transport by the mean meridional circulation increases with resolution in the deep tropics, while transport by transient eddies decreases. These changes are associated with enhanced gross moist stability that switches from negative to positive due to an increasingly top-heavy mean circulation and reduced eddy activity diffusing water vapor along an unchanging mean moisture gradient. Further analysis rules out extratropical baroclinic eddies and radiation as the main drivers of these changes. Instead, the resolution dependence of both the mean meridional circulation and transient eddies appears to reflect the resolution dependence of tropical explicit (unparameterized) deep convection. We speculate the multiscale interactions of convection allow for a coupling between gross moist stability and eddy moisture flux, leading to their concurrent changes with resolution. We discuss the implications of this resolution dependence for developing theories and models of the tropical atmosphere.
PB American Geophysical Union
SN 1942-2466
YR 2025
FD 2025-11-28
LK https://hdl.handle.net/20.500.14352/129372
UL https://hdl.handle.net/20.500.14352/129372
LA eng
NO Chang, C., Lin, P., Held, I. M., Merlis, T. M., & Zurita‐Gotor, P. (2025). Resolution Dependence of Tropical Poleward Energy Transport in Aquaplanet GCMs. Journal of Advances in Modeling Earth Systems, 17(12), e2025MS005103. https://doi.org/10.1029/2025MS005103
NO © 2025 The Author(s).AGS 2246700NTU-114V1063-1NA23OAR4320198
NO National Science Foundation (US)
NO Ministry of Education (Taiwan)
NO European Commission
NO Ministerio de Ciencia e Investigación (España)
NO Agencia Estatal de Investigación (España)
NO Cooperative Institute for Modeling the Earth System (US)
DS Docta Complutense
RD 25 mar 2026