Size, Shape and Spatial Arrangement of Mega-scale Glacial Lineations from a Large and Diverse Dataset

Authors

Matteo Spagnolo, University of Aberdeen
Chris D. Clark, University of Sheffield
Jeremy C. Ely, University of Sheffield
Chris R. Stokes, Durham University
John B. Anderson, Rice University
Karin Andreassen, University of Tromso
Alastair G. C. Graham, University of ExeterFollow
Edward C. King, Ice Sheets Programme, British Antarctic Survey

Document Type

Article

Publication Date

2014

Keywords

MSGL, glacial bedform, ice stream, morphometry

Digital Object Identifier (DOI)

https://doi.org/10.1002/esp.3532

Abstract

Mega-scale glacial lineations (MSGLs) are a characteristic landform on ice stream beds. Solving the puzzle of their formation is key to understanding how ice interacts with its bed and how this, in turn, influences the dynamics of ice streams. However, a comprehensive and detailed characterization of this landform's size, shape and spatial arrangement, which might serve to test and refine formational theories, is largely lacking. This paper presents a detailed morphometric analysis and comparison of 4043 MSGLs from eight palaeo-ice stream settings: three offshore (Norway and Antarctica), four onshore (Canada), and one from under a modern ice stream in West Antarctica. The length of MSGLs is lower than previously suggested (mode 1000–2000 m; median 2892 m), and they initiate and terminate at various locations on an ice stream bed. Their spatial arrangement reveals a pattern that is characterized by an exceptional parallel conformity (80% of all mapped MSGLs have an azimuth within 5° from the mean values), and a fairly constant lateral spacing (mode 200–300 m; median 330 m), which we interpret as an indication that MSGLs are a spatially self-organized phenomenon. Results show that size, shape and spatial arrangement of MSGLs are consistent both within and also generally between different ice stream beds. We suggest this results from a common mechanism of formation, which is largely insensitive to local factors. Although the elongation of MSGLs (mode 6–8; median 12.2) is typically higher than features described as drumlins, these values and those of their width (mode 100–200 m; median 268 m) overlap, which suggests the two landforms are part of a morphological continuum and may share a similar origin. We compare their morphometry with explicit predictions made by the groove-ploughing and rilling instability theories of MSGL formation. Although the latter was most compatible, neither is fully supported by observations.

Rights Information

This work is licensed under a Creative Commons Attribution 3.0 License.

Was this content written or created while at USF?

No

Citation / Publisher Attribution

Earth Surface Processes and Landforms, v. 39, issue 11, p. 1432-1448

Scholar Commons Citation

Spagnolo, Matteo; Clark, Chris D.; Ely, Jeremy C.; Stokes, Chris R.; Anderson, John B.; Andreassen, Karin; Graham, Alastair G. C.; and King, Edward C., "Size, Shape and Spatial Arrangement of Mega-scale Glacial Lineations from a Large and Diverse Dataset" (2014). Marine Science Faculty Publications. 1549.
https://digitalcommons.usf.edu/msc_facpub/1549