APL-UW

Ian Joughin

Senior Principal Engineer

Affiliate Professor, Earth and Space Sciences

Email

irj@uw.edu

Phone

206-221-3177

Biosketch

Ian Joughin continues his pioneering research into the use of differential SAR interferometry for the estimation of surface motion and topography of ice sheets. He combines the remote sensing with field work and modeling to solve ice dynamics problems. Solving the problems helps him understand the mass balance of the Greenland and Antarctic Ice Sheets in response to climate change.

In addition to polar research, he also contributed to the development of algorithms that were used to mosaic data for the near-global map of topography from the Shuttle Radar Topography Mission (SRTM).

Department Affiliation

Polar Science Center

Education

B.S. Electrical Engineering, University of Vermont, 1986

M.S. Electrical Engineering, University of Vermont, 1990

Ph.D. Electrical Engineering, University of Washington, 1995

Projects

Marine Ice Sheet Collapse in Thwaites Glacier Basin, West Antarctica

Airborne and satellite observations of West Antarctic topography and glacier flow speeds are combined with a computer model simulating ocean-driven glacier melting to show that the ice sheet's collapse is already underway. The onset of rapid collapse may begin in two centuries or a millennium from now

14 May 2014

Videos

A Response to "Catastrophic" Sea Level Rise Headlines

Glaciologist Ian Joughin responds to attention-grabbing headlines generated by a recently published study, which states that melting glaciers and ice sheets are likely to produce a catastrophic sea level rise of several meters within the century.

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28 Jul 2015

Joughin has spent more than two decades studying glacier and ice sheet dynamics, and modeling how rapidly the flow of ice and melt water is discharged to the oceans. He concurs with the forecasts of the Intergovernmental Panel on Climate Change (IPCC) that project a possible 1-m sea level rise over next century, which is cause for concern. But Joughin notes that it is an extremely remote possibility that current melt rates can be extrapolated to produce 10 feet of sea level rise over the same period.

Clocking Greendland's Glaciers: Ice-sheet-wide velocity mapping

5 Dec 2013

Publications

2000-present and while at APL-UW

Thwaites Glacier thins and retreats fastest where ice-shelf channels intersect its grounding zone

Chartrand, A.M., I.M. Howat, I.R. Joughin, and B.E. Smith, "Thwaites Glacier thins and retreats fastest where ice-shelf channels intersect its grounding zone," Cryosphere, 18, 4971-4992, doi:10.5194/tc-18-4971-2024, 2024.

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6 Nov 2024

Antarctic ice shelves buttress the flow of the ice sheet but are vulnerable to increased basal melting from contact with a warming ocean and increased mass loss from calving due to changing flow patterns. Channels and similar features at the bases of ice shelves have been linked to enhanced basal melting and observed to intersect the grounding zone, where the greatest melt rates are often observed. The ice shelf of Thwaites Glacier is especially vulnerable to basal melt and grounding zone retreat because the glacier has a retrograde bed leading to a deep trough below the grounded ice sheet. We use digital surface models from 2010–2022 to investigate the evolution of its ice-shelf channels, grounding zone position, and the interactions between them. We find that the highest sustained rates of grounding zone retreat (up to 0.7 km yr-1) are associated with high basal melt rates (up to ~250 m yr-1) and are found where ice-shelf channels intersect the grounding zone, especially atop steep local retrograde slopes where subglacial channel discharge is expected. We find no areas with sustained grounding zone advance, although some secular retreat was distal from ice-shelf channels. Pinpointing other locations with similar risk factors could focus assessments of vulnerability to grounding zone retreat.

Characterizing southeast Greenland fjord surface ice and freshwater flux to support biological applications

Moon, T.A., B. Cohen, T.E. Black, K.L. Laidre, H.L. Stern, and I. Joughin, "Characterizing southeast Greenland fjord surface ice and freshwater flux to support biological applications," Cryosphere, 18, 4845-4872, doi:10.5194/tc-18-4845-2024, 2024.

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29 Oct 2024

Southeast Greenland (SEG) is characterized by complex morphology and environmental processes that create dynamic habitats for top marine predators. Active glaciers producing solid-ice discharge, freshwater flux, offshore sea ice transport, and seasonal landfast-ice formation all contribute to a variable, transient environment within SEG fjord systems. Here, we investigate a selection of physical processes in SEG to provide a regional characterization that reveals physical system processes and supports biological research. SEG fjords exhibit high fjord-to-fjord variability regarding bathymetry, size, shape, and glacial setting, influencing some processes more than others. For example, during fall, the timing of offshore sea ice formation near SEG fjords progresses temporally when moving southward across latitudes, while the timing of offshore sea ice disappearance is less dependent on latitude. The rates of annual freshwater flux into fjords, however, are highly variable across SEG, with annual average input values ranging from ~1 x 108 to ~1.25 x 1010 m3 (~0.1–12.5 Gt) for individual fjords. Similarly, the rates of solid-ice discharge in SEG fjords vary widely — partly due to the irregular distribution of active glaciers across the study area (60–70°N). Landfast sea ice, assessed for eight focus fjords, is seasonal and has a spatial distribution highly dependent on individual fjord topography. Conversely, glacial ice is deposited into fjord systems year-round, with the spatial distribution of glacier-derived ice depending on the location of glacier termini. As climate change continues to affect SEG, the evolution of these metrics will vary individually in their response, and next steps should include moving from characterization to system projection. Due to the projected regional ice sheet persistence that will continue to feed glacial ice into fjords, it is possible that SEG could remain a long-term refugium for polar bears and other ice-dependent species on a centennial to millennial scale, demonstrating a need for continued research into the SEG physical environment.

Responses of the Pine Island and Thwaites glaciers to melt and sliding parameterizations

Joughin, I., D. Shapero, and P. Dutrieux, "Responses of the Pine Island and Thwaites glaciers to melt and sliding parameterizations," Cryosphere, 18, 2583-2601, doi:10.5194/tc-18-2583-2024, 2024.

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28 May 2024

The Pine Island and Thwaites glaciers are the two largest contributors to sea level rise from Antarctica. Here we examine the influence of basal friction and ice shelf basal melt in determining projected losses. We examine both Weertman and Coulomb friction laws with explicit weakening as the ice thins to flotation, which many friction laws include implicitly via the effective pressure. We find relatively small differences with the choice of friction law (Weertman or Coulomb) but find losses to be highly sensitive to the rate at which the basal traction is reduced as the area upstream of the grounding line thins. Consistent with earlier work on Pine Island Glacier, we find sea level contributions from both glaciers to vary linearly with the melt volume averaged over time and space, with little influence from the spatial or temporal distribution of melt. Based on recent estimates of melt from other studies, our simulations suggest that the combined melt-driven and sea level rise contribution from both glaciers may not exceed 10 cm by 2200, although the uncertainty in model parameters allows for larger increases. We do not include other factors, such as ice shelf breakup, that might increase loss, or factors such as increased accumulation and isostatic uplift that may mitigate loss.

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In The News

UW polar bear expert appears in BBC-produced film about the Arctic

UW News, Hannah Hickey

A new production, "Arctic: Our Frozen Planet," narrated by Benedict Cumberbatch, screens May 25 and 27 at the Pacific Science Center in Seattle. Eric Regehr, a researcher at the UW Applied Physics Laboratory, appears in the film doing fieldwork on Wrangel Island, an island off the northeast coast of Russia that is home to the world’s highest concentration of polar bears.

23 May 2023

Parts of Greenland Warmer Now Than in 1,000 Years

Axios, Andrew Freedman

The new research offers the first conclusive evidence of human-induced long-term warming and increased meltwater runoff in the northern and central parts of Greenland, typically the coldest parts of the ice sheet. Ian Joughin comments that the warming has a clear linear trend, which will likely steepen with time.

19 Jan 2023

Here are 3 dangerous climate tipping points the world is on track for

NPR, Rebecca Hersher and Lauren Sommer

Climate tipping points won't be as abrupt as that term would suggest. Most will unfold over the course of decades. Some could take centuries. Some may be partially reversible or avoidable. But they all have enormous and lasting implications for the humans, plants and animals on Earth.

10 Nov 2022

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