C14A-07
Physical characteristics of drumlins, with implications for their formation, at an active drumlin field, Múlajökull, Iceland

Monday, 14 December 2015: 17:30
3007 (Moscone West)
Reba G McCracken1, Neal R Iverson1, Ívar Örn Benediktsson2, Anders Schomacker3, Mark D Johnson4, Lucas Zoet1 and Thomas Hooyer5, (1)Iowa State University, Ames, IA, United States, (2)Lund University, Dept. of Geology, Lund, Sweden, (3)Norwegian University of Science and Technology, Trondheim, Norway, (4)University of Gothenburg, Gothenburg, Sweden, (5)Geosciences Department, Milwaukee, WI, United States
Abstract:
The forefield of Múlajökull—a warm-based, surge-type glacier in central Iceland—comprises the only known active drumlin field, with drumlins of similar morphometry to their Pleistocene counterparts but formed under better-known glaciological conditions.

Study of till magnetic and till fabrics, till densities and preconsolidation stresses, and drumlin stratigraphy indicates that drumlin relief reflects both erosion and deposition: 1) the package of basal tills that constitutes the drumlins thickens where the forefield has experienced more surging, but uniformities are common on drumlin flanks, 2) attitudes of till layers and patterns of deformation within them indicate till deposition occurred on drumlin slopes rather than prior to drumlinization, and 3) past effective stresses during quiescent periods were highest in interdrumlin areas.

These data suggest that erosion occurred during quiescence, rather than during surging, with erosion rates that increased under increasing effective stress. Stratigraphic evidence connecting specific till layers to surge moraines (Johnson et al., 2010, Geology 38, 943-6), on the other hand, indicates that deposition occurred during surges. Such deposition could have resulted from negative flux divergence in a shearing bed, but till fabrics provide no evidence for longitudinally compressive strain. A more likely origin for the basal till is that rapid, uniform bed shear during surging—consistent with the low and relatively uniform effective stresses expected during such periods—generated basal melt rates sufficient to release debris from ice and lodge it onto the bed. This conceptual model of alternating erosion and deposition implies drumlins formed by slow flowing ice elsewhere will be dominantly erosional, whereas drumlins with evidence of deposition may have experienced fast ice flow.