The Mystery of Hektoria Glacier's Rapid Retreat: Causes and Consequences

Tue Nov 04 2025 08:28:55 GMT+0200 (Eastern European Standard Time)

A new study sheds light on the rapid retreat of Hektoria Glacier in Antarctica, claiming it could indicate unprecedented rates of sea-level rise, while sparking debate among scientists over the glacier's behavior.

In late 2022, Hektoria Glacier experienced an extraordinary retreat, raising questions about its causes. Researchers suggest an unprecedented grounding glacier mechanism, which may lead to faster sea-level rise elsewhere in Antarctica. However, this theory faces skepticism from other experts regarding the glacier's behaviors and grounding line status.

When an Antarctic glacier was sparked into rapid retreat three years ago, it left scientists scratching their heads as to what might have caused it.

Hektoria Glacier retreated by more than 8km (5 miles) in just two months in late 2022 - and now a new study claims to have the answer.

The authors believe that Hektoria could be the first modern example of a process where the front of a glacier resting on the seabed rapidly destabilises.

That could lead to much faster sea-level rise if it happened elsewhere in Antarctica, they say.

But other scientists argue that this part of the glacier was actually floating in the ocean – so while the changes are impressive, they are not so unusual.

Floating tongues of glaciers extending into the sea – called ice shelves – are much more prone to breaking up than glacier fronts resting on the seabed.

That's because they can be more easily eaten away by warm water underneath.

Solving the 'whodunnit'

That Hektoria has undergone huge change is not contested. Its front retreated by about 25km (16 miles) between January 2022 and March 2023, satellite data shows.

But unravelling the causes is like a 'whodunnit' mystery, according to study lead author Naomi Ochwat, research affiliate at the University of Colorado Boulder and post-doctoral researcher at the University of Innsbruck.

The case began way back in 2002 with the extraordinary collapse of an ice shelf called Larsen B in the eastern Antarctic Peninsula. About 3250 sq km (1250 sq miles) of ice shelf was lost, roughly the size of Cambridgeshire or Gloucestershire.

Larsen B had been effectively holding Hektoria Glacier back. Without it, Hektoria's movement sped up and the glacier thinned.

But the bay vacated by the ice shelf was eventually filled with sea-ice fastened to the seabed, helping to partly stabilise Hektoria.

That was until early 2022, when the sea-ice broke up.

What followed was further loss of floating ice from the front of Hektoria, as large, flat-topped icebergs broke off or calved, and the ice behind sped up and thinned.

That is not unusual. Iceberg calving is a natural part of ice sheet behaviour, even though human-caused climate change makes the loss of ice shelves much more likely.

What was unprecedented, the authors argue, was what happened in late 2022, when they suggest the front of the glacier was grounded - resting on the seabed - rather than floating.

In just two months, Hektoria retreated by 8.2km. That would be nearly ten times faster than any grounded glacier recorded before.

This extraordinary change, the authors say, could be thanks to an ice plain - a relatively flat area of bedrock on which the glacier lightly rests.

Upward forces from the ocean water could lift the thinning ice essentially all at once, causing icebergs to break off and the glacier to retreat in quick time.

Glaciers don't usually retreat this fast, said co-author Adrian Luckman, professor of geography at Swansea University.

What makes this idea even more tantalising is that this process has never been observed in the modern world, the authors say. But markings on the seafloor suggest it may have triggered rapid ice loss into the ocean in the Earth's past.

What we see at Hektoria is a small glacier, but if something like that were to happen in other areas of Antarctica, it could play a much larger role in the rate of sea-level rise, said Dr Ochwat.

That could include Thwaites – the so-called doomsday glacier because it holds enough ice to raise global sea-levels by 65cm (26in) if it melted entirely.

But other researchers have contested the study's findings.

The controversy surrounds the position of the grounding line - where the glacier loses contact with the seabed and starts to float in the ocean.

Dr Frazer Christie, a glaciologist at Airbus Defence and Space, remarked on the significant disagreement within the glaciological community about the precise location of Hektoria Glacier's grounding line.

The location of the grounding line may sound trivial, but it is crucial to determine whether the change was truly unprecedented.

However, there is little debate that the fragile continent - once thought largely immune from global warming - is rapidly changing.

While we disagree about the process driving this change at Hektoria, we agree that the changes in the polar regions are scarily rapid, quicker than we expected even a decade ago, said Anna Hogg, professor of Earth observation at the University of Leeds.

We must collect more data from satellites to better monitor and understand why these changes are occurring and their implications for sea-level rise.