Earth's mightiest ocean current, the Antarctic Circumpolar Current (ACC), regulates
the exchange of heat and carbon between the ocean and the atmosphere, and influences
vertical ocean structure, deep-water production and the global distribution of nutrients
and chemical tracers. The eastward-flowing ACC occupies a unique circumglobal pathway
in the Southern Ocean that was enabled by the tectonic opening of key oceanic gateways
during the break-up of Gondwana (for example, by the opening of the Tasmanian Gateway,
which connects the Indian and Pacific oceans). Although the ACC is a key component
of Earth's present and past climate system, the timing of the appearance of diagnostic
features of the ACC (for example, low zonal gradients in water-mass tracer fields)
is poorly known and represents a fundamental gap in our understanding of Earth history.
Here we show, using geophysically determined positions of continent-ocean boundaries,
that the deep Tasmanian Gateway opened 33.5 ± 1.5 million years ago (the errors indicate
uncertainty in the boundary positions). Following this opening, sediments from Indian
and Pacific cores recorded Pacific-type neodymium isotope ratios, revealing deep westward
flow equivalent to the present-day Antarctic Slope Current. We observe onset of the
ACC at around 30 million years ago, when Southern Ocean neodymium isotopes record
a permanent shift to modern Indian-Atlantic ratios. Our reconstructions of ocean circulation
show that massive reorganization and homogenization of Southern Ocean water masses
coincided with migration of the northern margin of the Tasmanian Gateway into the
mid-latitude westerly wind band, which we reconstruct at 64° S, near to the northern
margin. Onset of the ACC about 30 million years ago coincided with major changes in
global ocean circulation and probably contributed to the lower atmospheric carbon
dioxide levels that appear after this time.