This article appeared in a journal published by Elsevier. The attached copy is furnished to the author for internal non-commercial research and education use, including for instruction at the authors institution and sharing with colleagues.Other uses, including reproduction and distribution, or selling or licensing copies, or posting to personal, institutional or third party websites are prohibited. Many coasts feature sequences of Quaternary and Neogene shorelines that are shaped by a combination of sealevel oscillations and tectonics. We compiled a global synthesis of sea-level changes for the following highstands: MIS 1, MIS 3, MIS 5e and MIS 11. Also, we date the apparent onset of sequences of paleoshorelines either from published data or tentatively extrapolating an age for the uppermost, purported oldest shoreline in each sequence. Including the most documented MIS 5e benchmark, we identify 926 sequences out of which 185 also feature Holocene shorelines. Six areas are identified where elevations of the MIS 3 shorelines are known, and 31 feature elevation data for MIS 11 shorelines. Genetic relationships to regional geodynamics are further explored based on the elevations of the MIS 5e benchmark. Mean apparent uplift rates range from 0.01 ± 0.01 mm/yr (hotspots) to 1.47 ± 0.08 mm/yr (continental collision). Passive margins appear as ubiquitously uplifting, while tectonic segmentation is more important on active margins. From the literature and our extrapolations, we infer ages for the onset of formation for~180 coastal sequences. Sea level fingerprinting on coastal sequences started at least during mid Miocene and locally as early as Eocene. Whether due to the changes in the bulk volume of seawater or to the temporal variations in the shape of ocean basins, estimates of eustasy fail to explain the magnitude of the apparent sea level drop. Thus, vertical ground motion is invoked, and we interpret the longlasting development of those paleoshore sequences as the imprint of glacial cycles on globally uplifted margins in response to continental compression. The geomorphological expression of the sequences matches the amplitude and frequency of glacial cyclicity. From middle Pleistocene to present-day, moderately fast (100,000 yrs) oscillating sea levels favor the development of well identified strandlines that are distinct from one another. Pliocene and Lower Pleistocene strandlines associated with faster cyclicity (40,000 yrs) are more compact and easily merge into rasas, whereas older Cenozoic low-frequency eustatic changes generally led to widespread flat-lying coastal plains.
Self-consistent landform assemblages suggest that Valles Marineris, the giant valley system that stretches along the Martian equator, was entirely glaciated during Late Noachian to Early Hesperian times and still contains huge volumes of fossil ice. Some of these glacial landform assemblages are illustrated here, with representative examples selected in three regions: Ius Chasma, Central Candor Chasma and the junction between Coprates Chasma and Capri Chasma. A morphological boundary separating an upper spur-and-gully morphology from a smooth basal escarpment has been spectacularly preserved along valley walls throughout Valles Marineris. The boundary winds around topographic obstacles and displays long-wavelength variations in elevation. It is associated with lateral benches, hanging valleys and truncated spurs. Comparisons with terrestrial analogs indicate that it is most reasonably interpreted as a glacial trimline. Chasma floors are covered by various kinds of terrains, including hummocky terrains, platy terrains, lateral banks, layered benches and a draping mantle. Landforms in these terrains and their spatial relationship with the interpreted trimline suggest that they correspond to various disintegration stages of an ancient glacial fill, currently protected by a superficial cover of ablation till. Altogether, these landforms and terrains compose a full glacial landsystem with wet-based glaciers that were able to flow and slide over their beds. It was most probably fed by ice accumulating at low elevations directly from the atmosphere onto valley floors and walls, with only minor contributions from tributary glaciers flowing down from higher elevations. Similar fossil glacial landsystems dating back from the early Martian history are to be expected in many other low-latitude troughs such as chasmata, chaos, valleys, impact craters and other basins.
Abstract. Ice streams are corridors of fast-flowing ice that control mass transfers
from continental ice sheets to oceans. Their flow speeds are known to
accelerate and decelerate, their activity can switch on and off, and even
their locations can shift entirely. Our analogue physical experiments reveal
that a life cycle incorporating evolving subglacial meltwater routing and bed
erosion can govern this complex transitory behaviour. The modelled ice
streams switch on and accelerate when subglacial water pockets drain as
marginal outburst floods (basal decoupling). Then they decelerate when the
lubricating water drainage system spontaneously organizes itself into
channels that create tunnel valleys (partial basal recoupling). The ice
streams surge or jump in location when these water drainage systems maintain
low discharge but they ultimately switch off when tunnel valleys have
expanded to develop efficient drainage systems. Beyond reconciling
previously disconnected observations of modern and ancient ice streams into
a single life cycle, the modelling suggests that tunnel valley development
may be crucial in stabilizing portions of ice sheets during periods of
climate change.
Abstract. Conceptual ice stream land systems derived from geomorphological and
sedimentological observations provide constraints on
ice–meltwater–till–bedrock interactions on palaeo-ice stream beds. Within
these land systems, the spatial distribution and formation processes of
ribbed bedforms remain unclear. We explore the conditions under which these
bedforms may develop and their spatial organization with (i) an experimental
model that reproduces the dynamics of ice streams and subglacial land systems
and (ii) an analysis of the distribution of ribbed bedforms on selected
examples of palaeo-ice stream beds of the Laurentide Ice Sheet. We find that
a specific kind of ribbed bedform can develop subglacially through soft-bed
deformation, where the ice flow undergoes lateral or longitudinal velocity
gradients and the ice–bed interface is unlubricated; oblique ribbed bedforms
develop beneath lateral shear margins, whereas transverse ribbed bedforms
develop below frontal lobes. We infer that (i) ribbed bedforms strike
orthogonally to the compressing axis of the horizontal strain ellipse of the
ice surface and (ii) their development reveals distinctive types of
subglacial drainage patterns: linked cavities below lateral shear margins
and efficient meltwater channels below frontal lobes. These ribbed bedforms
may act as convenient geomorphic markers to reconstruct lateral and frontal
margins, constrain ice flow dynamics, and infer meltwater drainage
characteristics of palaeo-ice streams.
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