Antarctic Bottom Water Warming and Freshening: Contributions to Sea Level Rise, Ocean Freshwater Budgets, and Global Heat Gain

Citation:
Purkey, SG, Johnson GC.  2013.  Antarctic Bottom Water Warming and Freshening: Contributions to Sea Level Rise, Ocean Freshwater Budgets, and Global Heat Gain. Journal of Climate. 26:6105-6122.

Date Published:

Aug

Keywords:

abyssal, balance, basin, bottom currents, bottom water, circulation, climate variability, deep, Energy budget, pacific-ocean, salinity, sea level, Southern Ocean, temperature trends, weddell sea, western south-atlantic

Abstract:

Freshening and warming of Antarctic Bottom Water (AABW) between the 1980s and 2000s are quantified, assessing the relative contributions of water-mass changes and isotherm heave. The analysis uses highly accurate, full-depth, ship-based, conductivity-temperature-depth measurements taken along repeated oceanographic sections around the Southern Ocean. Fresher varieties of AABW are present within the South Pacific and south Indian Oceans in the 2000s compared to the 1990s, with the strongest freshening in the newest waters adjacent to the Antarctic continental slope and rise indicating a recent shift in the salinity of AABW produced in this region. Bottom waters in the Weddell Sea exhibit significantly less water-mass freshening than those in the other two southern basins. However, a decrease in the volume of the coldest, deepest waters is observed throughout the entire Southern Ocean. This isotherm heave causes a salinification and warming on isobaths from the bottom up to the shallow potential temperature maximum. The water-mass freshening of AABW in the Indian and Pacific Ocean sectors is equivalent to a freshwater flux of 73 +/- 26 Gt yr(-1), roughly half of the estimated recent mass loss of the West Antarctic Ice Sheet. Isotherm heave integrated below 2000 m and south of 30 degrees S equates to a net heat uptake of 34 +/- 14 TW of excess energy entering the deep ocean from deep volume loss of AABW and 0.37 +/- 0.15 mm yr(-1) of sea level rise from associated thermal expansion.

Notes:

n/a

Website

DOI:

10.1175/JCLI-D-12-00834.1