In this study, the relationship between water vapor and atmospheric angular momentum's mass term (M_Ω) has been investigated using four reanalysis datasets for the years 1950–2020: ERA5, ERA-20C, JRA55, and NCEP/NCAR. The four reanalysis datasets revealed a consistent positive long-term trend in global M_Ω anomalies, while also identified shifts in the trend from negative to more positive in the period from the early to mid-1970s. Meanwhile, analysis of global water vapor trends shows that there is an additional mass of water vapor, which results in variations in water vapor surface pressure (p_w) of about ~0.3 mbar. The p_w was then used to estimate the contribution of water vapor to M_Ω, which is referred to as M_Ωw. Changes in the contribution of water vapor to M_Ω after the 1970s were calculated based on the anomaly of M_Ωw relative to the climatology value of 1970-1979. It can be shown that the M_Ωw anomalies tend to be positive after the 1970s period. In addition, the ratio of the M_Ωw anomalies relative to the global M_Ω suggests a change in the pattern of the contribution of water vapor to M_Ω, which is indicated from the fluctuation of this percentage every ten years. The highest contribution of water vapor to M_Ω occurred in the equatorial region during 2010-2020, with a ratio of M_Ωw to the increase in global M_Ω at 25-50%. The stability of the relationship between M_Ω and water vapor is examined using the 20 year shifting window correlation. The relationship between water vapor and M_Ω is more consistent on annual and interannual scales, especially in the equatorial region, but there are inconsistencies for longer time scales. Inconsistency between water vapor and M_Ω in the interdecadal scale is characterized by a lower statistical coherence from the mid-1980s to the 2000s, which indicates a decrease in the contribution of water vapor to M_Ω. These results suggest that water vapor alone is insufficient to account for the increase in M_Ω over the period.