Description: A large number of water masses are presented in the Atlantic Ocean, and knowledge of their distributions and properties is important for understanding and monitoring of a range of oceanographic phenomena. The characteristics and distributions of water masses in biogeochemical space are useful for, in particular, chemical and biological oceanography to understand the origin and mixing history of water samples. Here, we define the characteristics of the major water masses in the Atlantic Ocean as source water types (SWTs) from their formation areas, and map out their distributions. The SWTs are described by six properties taken from the biased-adjusted Global Ocean Data Analysis Project version 2 (GLODAPv2) data product, including both conservative (conservative temperature and absolute salinity) and non-conservative (oxygen, silicate, phosphate and nitrate) properties. The distributions of these water masses are investigated with the use of the optimum multi-parameter (OMP) method and mapped out. The Atlantic Ocean is divided into four vertical layers by distinct neutral densities and four zonal layers to guide the identification and characterization. The water masses in the upper layer originate from wintertime subduction and are defined as central waters. Below the upper layer, the intermediate layer consists of three main water masses: Antarctic Intermediate Water (AAIW), Subarctic Intermediate Water (SAIW) and Mediterranean Water (MW). The North Atlantic Deep Water (NADW, divided into its upper and lower components) is the dominating water mass in the deep and overflow layer. The origin of both the upper and lower NADW is the Labrador Sea Water (LSW), the Iceland–Scotland Overflow Water (ISOW) and the Denmark Strait Overflow Water (DSOW). The Antarctic Bottom Water (AABW) is the only natural water mass in the bottom layer, and this water mass is redefined as Northeast Atlantic Bottom Water (NEABW) in the north of the Equator due to the change of key properties, especially silicate. Similar with NADW, two additional water masses, Circumpolar Deep Water (CDW) and Weddell Sea Bottom Water (WSBW), are defined in the Weddell Sea region in order to understand the origin of AABW.

Description: The distribution of water masses, and the ventilation rates of these, are of significance to the thermohaline circulation and biogeochemistry of the world oceans. The distribution of the main water masses in the Atlantic Ocean is published in a companion study (Liu and Tanhua, 2021), their ages and ventilation time-scales are reported here by using observations of the transient tracers, CFC-12 and SF6. Two different definitions of water mass ages are presented; the mean-age representing an average age of a water mass, and the mode-age that better represents the advective time-scale. In general, ages increase with pressure and along the pathway of a water mass. The central waters in the upper layer obtain the mean-ages of up to ~100 years and the mode-ages of up to ~30 years. In the intermediate layer, the Antarctic Intermediate Water (AAIW) and the Mediterranean Water (MW) show gradients of water mass ages in the meridional and zonal direction respectively. The AAIW obtains the highest mean-age of ~300 years and mode-age of ~80 years at 30° N, while the MW shows the highest mean-age of ~400 years and mode-age of ~100 years in the equator region. As the dominant water mass in the deep and overflow layer, the North Atlantic Deep Water (NADW) from high northern latitudes obtains the highest mean-age of ~600 years and mode-age of ~100 years in the Antarctic Circumpolar Current (ACC) region at 50° S. In the bottom layer, the Antarctic Bottom Water (AABW) from the Weddell Sea obtains the highest mean-age of ~600 years and mode-age of ~100 years in the equator. As the continuation of AABW, the Northeast Atlantic Bottom Water (NEABW) obtains the highest mean-age of ~800 years and mode-age of ~120 years at 50° N. The mode-age increases with the transport distance from formation area, accompanied by significant differences between the eastern and western basins. The mode-age is used to calculate the oxygen utilization rate (OUR) with apparent oxygen utilization (AOU) during the active transport in water masses. The western basin exhibits lower mode-age with higher oxygen (low AOU) due to the better ventilation. The OUR shows similar distribution to dissolved oxygen (DO), indicating higher oxidation rate in the high oxygen region.