Your search keyword '"Bourman, Robert P."' showing total 54 results

51. The Adventures and Peregrinations of the Fabulous Five during Coastal Fieldwork in South Australia

Author

A.P. Belperio, Robert P. Bourman, J. H. Cann, Nick Harvey, Colin V. Murray-Wallace, Belperio, Antonio P, Bourman, Robert P, Cann, John H, Harvey, Nick, and Murray-Wallace, Colin V

Subjects

History, Ecology, coastal fieldwork, South Australia, memoir, Adventure, Archaeology, Earth-Surface Processes, Water Science and Technology

Abstract

Over the past several decades, a group of like-minded Earth scientists have made some useful contributions towards understanding the Quaternary coastal geology and geomorphology, particularly of South Australia, but also within a much wider Australian context.

Published

2020

52. Aminostratigraphy and thermoluminescence dating of coastal aeolianites and the later Quaternary history of a failed delta: The River Murray mouth region, South Australia

Author

David M. Price, John R. Prescott, A.P. Belperio, Frances M. Williams, Robert P. Bourman, Colin V. Murray-Wallace, Murray-Wallace, C, Bourman, Robert P, Prescott, John R, Williams, Francis, Price, David M, and Belperio, A

Subjects

Aminostratigraphy, Marine isotope stage, geography, geography.geographical_feature_category, Thermoluminescence dating, Pleistocene, Luminescence dating, River Murray, Coastal plain, Stratigraphy, Southern Australia, Geology, Quaternary sea-level changes, Amino acid racemization, Oceanography, Aeolianite, Interglacial, Earth and Planetary Sciences (miscellaneous), Glacial period, Quaternary, Holocene, Coastal sedimentation

Abstract

A geochronological framework for the sequential development of coastal barrier aeolianite complexes in the mouth region of the River Murray, Australia's largest river system is presented based on amino acid racemization and thermoluminescence dating. The sedimentary successions represent a foreshortened and condensed sequence of coastal barriers compared with those of the Coorong Coastal Plain in southern South Australia where the barrier complexes are more widely separated in response to tectonic uplift. The barriers have formed during interglacial sea-level highstands and are correlatives of genetically equivalent landforms of the Coorong Coastal Plain. Thermoluminescence dating and the extent of amino acid racemization in aeolianite 'whole-rock' sediment samples, reveal a general increase in age of the barriers landwards from the modern coastline. In detail, however, the individual barriers represent composite structures having formed in more than one interglaciation, due to the reoccupation of Pleistocene shoreline positions during sea-level highstands of similar amplitude, in a zone of gradual basin subsidence. The most seaward Pleistocene aeolianite at Surfer Beach is of interstadial age (Marine Isotope Stage 5c, 105 ± 5 ka; MIS 5c), and correlates with the Robe Range of the Coorong Coastal Plain. The last interglacial shoreline (130 ± 15 ka; MIS 5e) is particularly well-defined in the River Murray mouth region. It is represented by a complex association of coastal parabolic dunes superimposed on a transverse dune system, which runs parallel with the former coastline, and also includes associated estuarine, lagoonal and open ocean beach facies. Landward of the last interglacial succession are distinct barriers relating to the penultimate interglaciation (215 ± 35 ka; MIS 7), as well as earlier interglaciations (350 ± 65 ka; MIS 9 or 11 and 470 ± 70 ka; MIS 11 or 13). The coastal barriers have been successively breached by the ancestral River Murray at times of lower sea level during glacial cycles. Former mouths of the River Murray during interglacial sea-level highstands are likely to have existed near Tauwitchere Island during MIS 7, and between Goolwa and Hindmarsh Island and near the southern-most part of Lake Albert during the last interglacial (MIS 5e). The River Murray mouth region represents a failed delta as the limited sediment brought to this area since late middle Pleistocene time has been either rapidly incorporated within aeolian deposits during sea-level highstands, or transported to the edge of the Lacepede Shelf during glacial maxima. The Holocene and modern River Murray has not established a marine delta, but deposits its load in the settling basins of the terminal lakes. Only a small digitate delta has formed where the river enters Lake Alexandrina. © 2009 Elsevier B.V. All rights reserved.

Published

2010

53. Catchments and waterways

Author

Bourman, Robert P, Harvey, Nick, and Bryars, Simon

Subjects

market, water, prices

Published

2010

54. Holocene palaeofire records in a high-level, proximal valley-fill (Wilson Bog), Mount Lofty Ranges, South Australia

Author

Rowena H Morris, Lee J. Arnold, Richard G. Roberts, Katherine C. Brownlie, J. H. Cann, Colin V. Murray-Wallace, Solomon Buckman, Robert P. Bourman, Terry J. Lachlan, Buckman, Solomon, Brownlie, Katherine, Bourman, Robert P, Murray-Wallace, Colin, Morris, Rowena H, Lachlan, Terry J, Roberts, Richard G, Arnold, Lee J, and Cann, John

Subjects

Archeology, Global and Planetary Change, geography, pyrocolluviation, geography.geographical_feature_category, Peat, Ecology, valley-fill, Paleontology, Wetland, peat bog, Archaeology, Deposition (geology), law.invention, law, Aggradation, Radiocarbon dating, OSL, Bog, Holocene, Geology, charcoal, fire, Earth-Surface Processes, Colluvium

Abstract

An elevated valley-fill peat bog (Wilson Bog) near Mount Lofty, South Australia, failed in November 2005 following a flooding event, and exposed representative sections of the sediment infill. Two distinct units were revealed: 2 m of coarse-grained, siliciclastic sand/gravel, overlain by 2 m of peat. A simple charcoal extraction technique based on floatation and skimming was developed to extract coarse charcoal from coarse-grained gravels to determine the palaeofire record at a proximal site of sedimentation. Optically stimulated luminescence (OSL) dating of basal sediments revealed a minimum age of deposition of 7.02 +0.50—0.56 ka, while the oldest charcoal peak yielded a radiocarbon age of 6000—5740 cal. yr BP. The lower half of the siliciclastic unit contains three distinct charcoal peaks suggesting there were infrequent but intense fires associated with wetter conditions during the Holocene climatic optimum 8000—5000 years ago. The period from 4000 to 2000 cal. yr BP is characterised by more frequent charcoal peaks and higher background levels of charcoal, which is consistent with more regular but less intense fires during drier, cooler conditions. The sharp transition from siliciclastic sedimentation to peat formation began ~1200 cal. yr BP, which may relate to a return to wetter conditions. However, fire frequency appears to have increased in this time suggesting augmentation by anthropogenic or ENSO-related factors. Charcoal-rich layers in the siliciclastic unit are associated with poorly sorted, bimodal sediments with high proportions of clay, silt and gravel, which supports the hypothesis that there is an association between past fire events and rapid, coarse-grained, post-fire aggradation. By analogy with active colluvial aggradation following recent fires at nearby Mount Bold, it is evident that fire plays a significant role in hillslope destabilization and subsequent sediment movement, leading to rapid valley-fill aggradation — a chain of events to which we apply the term ‘pyrocolluviation’.

Published

2009