Your search keyword '"Hedding, David W."' showing total 6 results

1. PRONIVAL RAMPARTS: ORIGIN AND DEVELOPMENT OF TERMINOLOGY

Author

Hedding, David W.

Published

2016

2. A spatial model of Marion Island's palaeo-ice extent.

Author

Rudolph, Elizabeth M., Hedding, David W., and Nel, Werner

Subjects

GEOMORPHOLOGY, LAST Glacial Maximum, ISLANDS, SOIL formation, SPECIES distribution, LANDFORMS

Abstract

Sub-Antarctic Marion Island's glacial history has acted as a control on abiotic terrestrial processes and the colonization and distribution of biotic species found on the island today. Recent chronological studies have shown an early deglaciation of the island and identified new geomorphological features associated with past ice dynamics. These permit a reassessment of ice extent during and after the island's last local glacial maximum. In this paper, we provide a revised reconstruction of the island's palaeo-ice extent by using a geomorphology-based approach to delineate palaeo-ice margins and demarcate possible glacial basins. The model presented here provides the needed spatial context for future studies on the variations in the distribution of species (e.g. microorganisms and plant species) and abiotic processes and forms (e.g. soil development and periglacial landforms). In addition, it highlights areas that require improved geophysical assessment in order to produce a more complete island-scale reconstruction of former ice extents (e.g. the west coast). [ABSTRACT FROM AUTHOR]

Published

2022

3. Geomorphological processes and landforms of glacier forelands in the upper Aktru River basin (Gornyi Altai), Russia: evidence for rapid recent retreat and paraglacial adjustment.

Author

Hedding, David W., Erofeev, Aleksander A., Hansen, Christel D., Khon, Alexey V., and Abbasov, Zamir R.

Subjects

GLACIAL landforms, WATERSHEDS, LANDFORMS, GLACIERS, AERIAL photography, DRONE aircraft

Abstract

The glaciers in the Aktru River basin of Gornyi Altai, Russia currently represent some of the fastest receding glaciers in the world. Formation of the morainic complexes closest to the contemporary glaciers in the Aktru River basin took place during the 17th - 18th centuries with recession commencing at the end of the 18th century. Coupled with this glacial retreat, earth surface processes and vegetation succession are responding to shape the glacier forelands. This article presents the first geomorphological maps for the upper reaches of the Aktru River basin and focuses on the geomorphological landforms that occur in the rapidly changing glacier forelands. Geomorphological mapping is difficult in steep mountainous regions and, thus, mapping was completed using satellite imagery, field mapping and observations coupled with highresolution aerial photography obtained from Unmanned Aerial Vehicles (UAVs). Critical steps of the procedure used to process UAV imagery and difficulties encountered in this mountainous terrain are noted. The acquired spatial data enable the mapping and classification of small-scale transient geomorphological features such as talus, glacial and glaciofluvial landforms. Their dynamics provide insights into supraglacial and subglacial processes of the glaciers of the Aktru River basin and subsequent paraglacial adjustment. The presented highresolution spatial data, which can also be obtained at high temporal resolutions in the future, can act as a reference frame for geomorphologists and ecologists studying the temporal evolution of glacier forelands of the Aktru River basin during paraglacial adjustment and subsequent colonisation and stabilisation by biota. [ABSTRACT FROM AUTHOR]

Published

2020

4. Aeolian processes and landforms in the sub-Antarctic: preliminary observations from Marion Island.

Author

Hedding, David W., Nel, Werner, and Anderson, Ryan L.

Subjects

EOLIAN processes, LANDFORMS, PLANT dispersal, SOLIFLUCTION, ISLANDS, WIND speed

Abstract

Sub-Antarctic Marion Island has a hyperoceanic climate, with cold and wet conditions and consistently strong wind velocities throughout the year. Recent observations recognized the increasing role of aeolian processes as a geomorphic agent, and this paper presents the first data for transport by aeolian processes on a sub-Antarctic island. Data were collected through an intensive and high-resolution measurement campaign at three study sites using Big Spring Number Eight sediment traps and surface sediment samplers in conjunction with an array of climatic and soil logger sensors. Observed aeolian landforms are megaripples, and the data suggest that aeolian processes are also modifying solifluction landforms. The sediment traps and sediment samplers collected wind-blown scoria at all three study sites, and the annual (horizontal) aeolian sediment flux extrapolated from this preliminary data is estimated at 0.36–3.85 kg cm−2 y−1. Importantly, plant material of various species was trapped during the study that suggests the efficiency of wind for the dispersal of plants in this sub-Antarctic environment may be underestimated. This paper advocates long-term monitoring of aeolian processes and that the link between aeolian processes and synoptic climate must be established. Furthermore, wind as a means to disperse genetic material on Marion Island should be investigated. [ABSTRACT FROM AUTHOR]

Published

2015

5. SPATIAL INVENTORY OF LANDFORMS IN THE RECENTLY EXPOSED CENTRAL HIGHLAND OF SUB-ANTARCTIC MARION ISLAND.

Author

Hedding, David W.

Subjects

*LANDFORMS, *INVENTORIES, *GLOBAL Positioning System, *GEOMORPHOLOGY

Abstract

Until recently, the Central Highland of sub-Antarctic Marion Island (above 750m a.s.l.) was covered by snow. Climatic amelioration is deemed responsible for the disappearance of the former permanent snowline which had a lower altitudinal limit of approximately 650m a.s.l. during the early-1950s. The recent sub-aerial exposure of this area now enables the geology and geomorphology to be documented. Mapping incorporated air-photo interpretation and field surveys using a hand-held Global Positioning System (GPS) to ensure spatial accuracy. Most grey lava outcrops above 750m a.s.l. exhibit some evidence of previous glaciations whereas black lava flows show no evidence of the effects of glaciers and must, therefore, post-date the Last Glacial Maximum (LGM). Frost processes currently predominate in the Central Highland, but there is a conspicuous lack of periglacial landforms (i.e. patterned ground) in scoria and grey lava areas. With the exception of thermal contraction cracking at one location, no other evidence for the development of geomorphological landforms in black lava areas exists. Other geomorphological landforms include meltout features, a manifestation of landscape process responses to climatic amelioration, mass movement landforms and the emergence of rudimentary aeolian landforms. Receding snow cover may enhance frost and aeolian processes, which could result in an interesting myriad of geomorphological landforms. [ABSTRACT FROM AUTHOR]

Published

2008

6. Formation of a pronival rampart on sub-Antarctic Marion Island.

Author

Hedding, David W., Sumner, Paul D., Holness, Stephen D., and Meiklejohn, K. Ian

Subjects

INCLINED planes, SLOPES (Physical geography), LANDFORMS, CLIMATE change detection, SLOPE stability, GROWTH, SNOW mechanics

Abstract

The formation of a pronival (protalus) rampart on sub-Antarctic Marion Island is investigated. Morphological attributes show debris at the angle of repose on the rampart's proximal slope and at a lower angle on the distal slope. Relative-age dating, based on the percentage moss cover and weathering rind thickness of the elastic component, indicates accumulation mainly on the proximal slope and rampart crest, implying upslope (retrogressive) accumulation. This contrasts with a previously published model for pronival ramparts, which proposes rampart growth by addition of material to the distal slope. Development of the Marion Island rampart is suggested to result from the control exerted by a relatively low-angled surface and a shrinking snowbed. A small debris step formed on the proximal slope appears to be a response to decreased snowfalls due to changing climate over the last c. 50 years. Growth rate of the rampart is considered to be variable during the Holocene in response to changes in climate and debris supply. [ABSTRACT FROM AUTHOR]

Published

2007