Your search keyword '"Seth Camp"' showing total 3 results

1. Microstructures in a shear margin: Jarvis Glacier, Alaska

Author

Christopher Gerbi, Stephanie Mills, Renée Clavette, Seth Campbell, Steven Bernsen, David Clemens-Sewall, Ian Lee, Robert Hawley, Karl Kreutz, and Kate Hruby

Subjects

Anisotropic ice, arctic glaciology, structural glaciology, Environmental sciences, GE1-350, Meteorology. Climatology, QC851-999

Abstract

Microstructures, including crystallographic fabric, within the margin of streaming ice can exert strong control on flow dynamics. To characterize a natural setting, we retrieved three cores, two of which reached bed, from the flank of Jarvis Glacier, eastern Alaska Range, Alaska. The core sites lie ~1 km downstream of the source, with abundant water present in the extracted cores and at the base of the glacier. All cores exhibit dipping layers, a combination of debris bands and bubble-free domains. Grain sizes coarsen on average approaching the lateral margin. Crystallographic orientations are more clustered and with c-axes closer to horizontal nearer the lateral margin. The measured fabric is sufficiently weak to induce little mechanical anisotropy, but the data suggest that despite the challenging conditions of warm ice, abundant water and a short flow distance, many aspects of the microstructure, including measurable crystallographic fabric, evolved in systematic ways.

Published

2021

2. The impact of temperature and crystal orientation fabric on the dynamics of mountain glaciers and ice streams

Author

Kate Hruby, Christopher Gerbi, Peter Koons, Seth Campbell, Carlos Martín, and Robert Hawley

Subjects

Anisotropic ice flow, glacier flow, glaciological model experiments, ice rheology, ice streams, Environmental sciences, GE1-350, Meteorology. Climatology, QC851-999

Abstract

Streaming ice accounts for a major fraction of global ice flux, yet we cannot yet fully explain the dominant controls on its kinematics. In this contribution, we use an anisotropic full-Stokes thermomechanical flow solver to characterize how mechanical anisotropy and temperature distribution affect ice flux. For the ice stream and glacier geometries we explored, we found that the ice flux increases 1–3% per °C temperature increase in the margin. Glaciers and ice streams with crystallographic fabric oriented approximately normal to the shear plane increase by comparable amounts: an otherwise isotropic ice stream containing a concentrated transverse single maximum fabric in the margin flows 15% faster than the reference case. Fabric and temperature variations independently impact ice flux, with slightly nonlinear interactions. We find that realistic variations in temperature and crystallographic fabric both affect ice flux to similar degrees, with the exact effect a function of the local fabric and temperature distributions. Given this sensitivity, direct field-based measurements and models incorporating additional factors, such as water content and temporal evolution, are essential for explaining and predicting streaming ice dynamics.

Published

2020

3. Explaining mass balance and retreat dichotomies at Taku and Lemon Creek Glaciers, Alaska

Author

Christopher McNeil, Shad O'Neel, Michael Loso, Mauri Pelto, Louis Sass, Emily H. Baker, and Seth Campbell

Subjects

Applied glaciology, climate change, glacier mass balance, glacier monitoring, mountain glaciers, Environmental sciences, GE1-350, Meteorology. Climatology, QC851-999

Abstract

We reanalyzed mass balance records at Taku and Lemon Creek Glaciers to better understand the relative roles of hypsometry, local climate and dynamics as mass balance drivers. Over the 1946–2018 period, the cumulative mass balances diverged. Tidewater Taku Glacier advanced and gained mass at an average rate of +0.25 ± 0.28 m w.e. a–1, contrasting with retreat and mass loss of −0.60 ± 0.15 m w.e. a−1 at land-terminating Lemon Creek Glacier. The uniform influence of regional climate is demonstrated by strong correlations among annual mass balance and climate data. Regional warming trends forced similar statistically significant decreases in surface mass balance after 1989: −0.83 m w.e. a–1 at Taku Glacier and −0.81 m w.e. a–1 at Lemon Creek Glacier. Divergence in cumulative mass balance arises from differences in glacier hypsometry and local climate. Since 2013 negative mass balance and glacier-wide thinning prevailed at Taku Glacier. These changes initiated terminus retreat, which could increase dramatically if calving begins. The future mass balance trajectory of Taku Glacier hinges on dynamics, likely ending the historic dichotomy between these glaciers.

Published

2020