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Pronival rampart and protalus rampart: a review of terminology

Published online by Cambridge University Press:  08 September 2017

D.W. Hedding
D.W. Hedding*
Affiliation:
Department of Geography, University of South Africa, Florida Campus, Florida 1710, South Africa E-mail: [email protected]
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Abstract

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Type
Correspondence
Information
Journal of Glaciology , Volume 57 , Issue 206 , 2011 , pp. 1179 - 1180
Copyright
Copyright © International Glaciological Society 2013

In the late 1980s, a series of letters in this journal (e.g. Reference ButlerButler, 1986, Reference Butler1987; Reference BallantyneBallantyne, 1987; Reference PorterPorter, 1987; Reference UnwinUnwin, 1988; Reference WilsonWilson, 1988) described the history of the early work on ‘pro-talus ramparts’. These letters also highlighted that many different terms, such as winter-talus ridge (Reference DalyDaly, 1912), nivation ridge (Reference BehreBehre, 1933) and protalus rampart (Reference BryanBryan, 1934), have been used to denote these discrete debris accumulations found at the foot of firn fields. The most common of these terms was ‘protalus rampart’ and it became entrenched in the literature (Reference BallantyneBallantyne, 1987) until it evolved yet again when Reference Shakesby, Matthews and McCarrollShakesby and others (1995) proposed replacing the descriptor ‘protalus’ with ‘pronival’ since they concluded that the latter provided a universally appropriate term to describe firn-foot debris accumulations; regardless of their position on the slope. The descriptor ‘pronival’ has largely gained acceptance in the literature (e.g. Reference HeddingHedding, 2008), while some studies (e.g. Reference Hedding, Meiklejohn, Le Roux, Loubser and DavisHedding and others, 2010) use ‘pronival (protalus)’ so as to avoid any ambiguity. Several recent studies (e.g. Reference LewisLewis, 2011) continue to use the descriptor ‘protalus’ since interchanging the descriptor ‘protalus’ with ‘pronival’ has not been very problematic in the literature thus far. Reference Scapozza, Lambiel, Baron, Marescot and ReynardScapozza and others (2011) have, however, recently proposed that the term ‘protalus rampart’ be used to define small permafrost creep phenomena (embryonic rock glaciers) in contrast to the former usage of the term to describe pronival ramparts. This may lead to some confusion in the literature because the differentiation of embryonic rock glaciers from pronival ramparts may prove difficult, particularly in relict features, since these features are morphologically similar. To further compound the difficulty in differentiating these features, many of the existing ‘diagnostic criteria’ used to identify pronival ramparts are plagued by circular arguments and assumptions about typical form, constituent material and genesis (Reference ShakesbyShakesby, 1997). Therefore, this letter aims to determine whether the terms ‘protalus rampart’ and ‘pronival rampart’ can coexist in literature by investigating the applicability of existing ‘diagnostic criteria’ that may be used to differentiate embryonic rock glaciers from pronival ramparts.

A pronival rampart, formerly referred to as a protalus rampart, is defined as a ridge, series of ridges or ramp of debris formed at the downslope margin of a perennial or semi-permanent snow bed, which is typically located near the base of a steep bedrock slope in a periglacial environment (Reference Shakesby and GoudieShakesby, 2004). Reference ShakesbyShakesby (1997) highlights that pronival ramparts are mostly viewed as separate, independently produced forms of modified talus occurring in a nondevelopmental morphological continuum of unmodified talus, but other researchers (e.g. Reference HaeberliHaeberli, 1985) argue that ramparts represent part of a linear developmental continuum of rock-glacier and moraine formation. Stemming from the work of Reference HaeberliHaeberli (1985), Reference Scapozza, Lambiel, Baron, Marescot and ReynardScapozza and others (2011) have recently proposed that the term ‘protalus rampart’ be used to define small permafrost creep phenomena (embryonic rock glaciers). The alternative usage of the term ‘protalus rampart’ by Reference Scapozza, Lambiel, Baron, Marescot and ReynardScapozza and others (2011) within the new genetic definition of active rock glaciers as the visible expression of cumulative deformation by long-term creep of ice/debris mixtures under periglacial conditions (Reference BerthlingBerthling, 2011) may, in theory, allow the term ‘protalus rampart’ to coexist with ‘pronival rampart’. However, the morphological similarities of pronival ramparts and incipient or immature rock glaciers make it difficult to distinguish between these features in the field. Pronival ramparts are typically differentiated from embryonic rock glaciers through the identification of specific morphological and sedimentological characteristics (Reference Hedding, Meiklejohn, Le Roux, Loubser and DavisHedding and others, 2010), but use of these ‘diagnostic criteria’ may prove inappropriate when differentiating embryonic rock glaciers from pronival ramparts.

Reference Curry, Walden and CheshireCurry and others (2001) indicate that well-developed protalus rock glaciers can be differentiated from pronival ramparts since these features are typically lobate in plan form, greater in length (downslope) than in width (across-slope), exhibit a convex distal slope, terminate >70 m from the talus slope and most distinctively they comprise meandering and closed depressions, downslope ridges and furrows, and transverse ridges and depressions. Many of these ‘diagnostic criteria’ are, however, inappropriate for the positive identification of embryonic rock glaciers since these features would lack many of the characteristics of well-developed protalus rock glaciers; making it extremely difficult to differentiate these features from pronival ramparts in the field. To further complicate the differentiation of pronival ramparts from embryonic rock glaciers, Reference ShakesbyShakesby (1997) highlights that, although rampart development is the result ofsupranival and subnival processes, pronival ramparts may also comprise permafrost and exhibit associated permafrost creep. Therefore, the identification of permafrost creep cannot be used to positively differentiate embryonic rock glaciers from pronival ramparts. In addition, Reference Shakesby, Matthews, McEwen and BerrisfordShakesby and others (1999) have identified snow creep as a subnival process responsible for pronival rampart formation, and snow creep may generate various morphological characteristics that may be exhibited by embryonic rock glaciers derived from permafrost creep. Thus this letter rejects the alternative usage of the term ‘protalus rampart’ to denote embryonic rock glaciers until such time as diagnostic criteria are identified by which pronival ramparts can be differentiated from other talus-derived landforms. Instead, it is suggested that ‘protalus rock glacier’ be used to denote embryonic rock glaciers. This is critical to avoid the incorrect identification and associated pal aeoenvi ron mental inferences that have plagued research on pronival ramparts in the past; particularly since relict protalus rock glaciers could be used to infer former permafrost conditions whereas pro-nival ramparts do not require permafrost for their formation.

27 October 2011

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