Ken Fortino stands atop the ice feature in his bug jacket. Ken and Dendy Lofton first noticed exposed ice beneath the tundra in late-June.

Two weeks later, even more ice is visible as the tundra thaws and sloughs away from the ice mound.

Our first question was, ‘How old is this ice? Has it existed since the last glacial maximum (~25,000 years ago)?’ This was the late-Pleistocene epoch – the most recent Ice Age when large mammals, such as woolly mammoths, scimitar cats and the giant beaver, roamed in the far north.

To find out, I contacted Dr. Skip Walker at UAF’s Alaska Geobotany Center. Dr. Walker recently lead a field trip in northern Alaska for the 9th International Permafrost Conference that was held in Fairbanks in late June.

The Arctic is underlain by continuous permafrost. These soils remain perennially frozen. However the upper-most layer of the tundra, or the active layer, thaws each summer. Plant roots penetrate the active layer and a suite of insects, fungi and microbes thrive within these annually thawed soils. The depth of the active layer varies across the tundra landscape. At Toolik Lake, the average maximum thaw depth in early August is about 75 cm.

An important landscape feature that influences the depth of the active layer is the overlying plant community. For example, in the tundra within the vicinity of the field station those areas with peat moss (Sphagnum spp.) will have a shallow depth of thaw. The peat moss insulates the permafrost below and these soils remain largely frozen. For this reason, a simple disturbance of the tundra vegetation can significantly affect the permafrost beneath.

When the permafrost thaws extensively, large depressions can occur in the tundra. We call this phenomenon “thermokarst.” Thermokarst originates when the ice-rich permafrost thaws and the ground beneath collapses. On slopes and riverbanks, thermokarst results in chunks of tundra sloughing into the valleys below.

Last week, we took advantage of a snow day to visit the ice feature again. The site is accessible via the maintenance road that parallels the Trans-Alaska Pipeline north to the oil fields at Prudhoe Bay on the Arctic Ocean.

The tundra continues to slough and even more of the ice feature is exposed.

I sent Dr. Walker these photos and identified the ice as, ‘a curious ground ice feature.’

His e-mail response began, “Oh, that’s a CGIF.”

I panicked and thought to myself, “What’s a CGIF? Is that an acronym I should be familiar with?”

I re-read my initial inquiry and realized CGIF was an acronym for our original terminology; ‘curious ground ice feature.’

We learned from Dr. Walker that this ice is not old. It likely formed over the previous year. Dr. Walker hypothesized that these features form when water flows between the peat moss and the mineral soil. This water then freezes and the tundra heaves upward during the winter months. Apparently, these types of ice features are quite common in the northern foothills of the Brooks Range.

The ‘CGIF.’

Although CGIFs are common, they do not have a formal name. Collectively, the field trip participants called them, ‘ice-cored mounds.’

I must admit, I was disappointed that the ice was so young. I yearn for a glimpse of the last Ice Age. While I may never see a live giant beaver, it is still possible that I will one day see, touch and taste ice that formed during the late Pleistocene.

Yup, I did indeed eat an ice-cube size chunk of the CGIF.

A polar grass (Arctagrostis latifolia) inflorescence bends under the weight of our recent July snowfall.