A new study by researchers from the Institute of Atmospheric Physics of the Chinese Academy of Sciences challenges traditional climate research frameworks. It demonstrates the pivotal role of nonlinear energy processes in shaping the zonal asymmetry observed in El Niño-Southern Oscillation (ENSO)-induced Pacific-North American (PNA) wave trains.
The study was published in Geophysical Research Letters on Sept. 7.
The researchers found that nonlinear energy processes played a crucial role in shaping the zonal asymmetry observed in ENSO-induced Pacific-North American wave patterns, which challenges traditional linear frameworks.
The researchers found that ENSO triggered a complex interplay of zonally symmetric and asymmetric responses within the atmosphere, ultimately affecting the positioning of Pacific-North American teleconnections. The nonlinear energy advection processes drive contrasting energy advection modes during El Niño and La Niña events, leading to variations in the zonal position of the Pacific-North American pattern.
The team's findings have been successfully reproduced and confirmed in model experiments of varying complexity, verifying the significance of nonlinear energy processes in shaping ENSO-induced teleconnections.
This study sheds new light on intricate mechanisms in ENSO-induced teleconnections, and emphasizes the need to consider nonlinear energy processes in climate research.
