Changes in the Global Climate: Atmospheric Angular Momentum and Pacific Ocean Temperatures

Atmospheric angular momentum (AAM) is used to study the variability of Earth's atmospheric circulation during the past 45 years, a time of considerable climate change. Using global AAM, two interdecadal states are defined covering the periods 1977-98 (hereinafter P1) and 1999-2022 (P2). Global AAM decreased from P1 to P2 and was accom-panied by weakened subtropical jet streams in both hemispheres, strong convection around the northern Maritime Conti-nent, and a strengthened sea surface temperature (SST) gradient across the tropical Pacific Ocean. The period differences project onto 1) internal interdecadal Pacific variability (IPV), 2) a postulated transient ocean thermostat response to green-house gas and aerosol emissions, and 3) circulation anomalies related to the ozone hole. During 1977-2023, the first two processes are forcing the climate toward larger Pacific Ocean SST gradients and a poleward expansion of the Indo-Pacific warm pool (IPWP), especially into the Northern Hemisphere. The ozone hole produces its own distinct pattern of anoma-lies in the Southern Hemisphere that tend to become persistent in the early 1990s. The zonal and vertical mean AAM var-iations during P1 have frequent westerly wind anomalies between 40 & DEG;N and 40 & DEG;S with poleward propagation on interannual time scales. During P2, the circulation is dominated by subtropical easterly wind anomalies, poleward-shifted jets, and weaker propagation. Locally, the zonal mean anomalies manifest as midlatitude ridges that lead to continental droughts. Case studies illustrate the weakened subtropical jet streams of P2 and examine the factors behind a transition to La Nifia in early 2020 that maintains the P2 pattern.