Testing the Origins of the Blue Ridge Escarpment

Bank, Gregory Charles

02 September 2001

Long, linear, high-relief escarpments mark many of the world's passive margins. These Great Escarpments have been interpreted to be the result of isostatic flexure, parallel slope retreat, and divide migration which accompanies rifting. It is unclear whether all these escarpments share this origin. Also uncertain is whether these features are formed via stable, steady-state processes or by climatic shifts or tectonic rejuvenation. The Blue Ridge Escarpment, eastern North America's great escarpment, is no different. A number of hypotheses attempt to explain the Blue Ridge Escarpment. These include lithologic variation between Blue Ridge and Piedmont rocks, the distance to ultimate base level, as well as, escarpment retreat resulting from post/syn-rift warping or faulting. We approach this problem from two directions. The first involves topographic comparisons and geologic observations to recognize and track divide migration. The second approach uses U-Th/He thermochronometry along two scarp-normal transects. Topographic analysis used data extracted from DEMs to compare three zones - the Upland, the Piedmont and the scarp zone itself. Parameters such as relief, drainage density, hypsometry, and slope are often used as proxies for relative erosion rates and the degree of maturity of a landscape. Results from these analyses indicate that the Upland and Piedmont zones are distinct landscapes, sharing very few topographic similarities, yet neither appears significantly more erodible than the other. Examination of parameters in the proximity of the escarpment point toward more rapid erosion here. Field evidence of this rapid scarp erosion (and thus divide migration) lies in the presence of beheaded stream channels, cobble roundness, and clast provenance. U-Th/He thermochronometry is a low temperature technique that allows us to calculate when rock cooled below 60-70C. Temperature is used as a proxy for depth, from which we can extract an exhumation rate. This method allows us to further test scarp genesis hypotheses. Preliminary results show older ages (~160) from the Upland surface than on the Piedmont lowland (~100 Ma). This confirms that the Piedmont surface is distinct from the Upland and demonstrates that it has experienced greater erosion. There is also some indication that ages "jump" across the Bowens Creek/Brevard fault system. Lastly, the ages appear to become younger approaching the escarpment which is indicative of scarp migration. As these results are preliminary, more data is required to prove or disprove these conclusions. / Master of Science

Blue Ridge Escarpment

landscape evolution

Great Escarpments

(U-Th)/He thermochronometry

Vivre dans des conditions difficiles en falaise : potentialités et longévité du genévrier de Phénicie (Juniperus Phoenicea L) / Living in harsh cliff conditions : potentialities and longevity of the Juniperus Phoenicea L

Mathaux, Coralie

30 March 2017

Les falaises sont les derniers écosystèmes vierges de la zone tempérée. Elles représentent un réservoir de biodiversité et un refuge pour de nombreuses espèces végétales et peuvent abriter des espèces longévives. Dans le bassin méditerranéen, la rareté des populations anciennes et naturelles et même celle d’arbres isolés qui atteignent des âges importants s’explique par l’existence d’une pression anthropique forte depuis environ 10 000 ans. Pourtant, dans les gorges de l’Ardèche (sud de la France), des populations de Juniperus phoenicea en falaise présentent toutes les classes d’âges y compris des individus millénaires. Les falaises abritent de façon régulière des vieux arbres qui peuvent être identifiés à l’aide de critères morphologiques visuels. Néanmoins, les parois rocheuses imposent aux arbres qui s’y développent des contraintes importantes liées à la verticalité et à la compacité du substrat. Le sol y est absent ou très réduit et cela entraîne un apport en eau et en nutriments qui peut également être limité. De plus, la verticalité du milieu entraîne de nombreuses chutes de pierres qui blessent ou tuent les arbres. Les genévriers de Phénicie qui colonisent ces milieux très contraignants, répondent à cette pression par un très faible taux de croissance, une mortalité partielle de l’appareil aérien et du cambium, des caractéristiques morphologiques foliaires adaptées à la sécheresse, une capacité à utiliser l’eau des brouillards et des petites pluies qui mouillent uniquement le feuillage et ils possèdent également des communautés de champignons mycorhiziens à arbuscules adaptées à ce milieu et ce tout en pouvant atteindre des longévités exceptionnelles. / The cliffs are the last virgin ecosystems of the temperate zone. They represent a reservoir of biodiversity and a refuge for many plant and animal species and can harbor long-lived species. In the Mediterranean basin, the scarcity of old and natural forest populations and even that of isolated trees reaching great ages is explained by the existence of a strong anthropogenic pressure for about 10 000 years. However, in the gorges of the Ardèche (southern France), populations of Juniperus phoenicea in cliffs present all age classes including millennial individuals. Beyond this, the cliffs regularly shelter old trees that can be identified using visual morphological criteria. Nevertheless, the rock walls impose important stresses on the trees which develop therein due to the verticality and the compactness of the substrate. The soil is absent or very reduced and this leads to a supply of water and nutrients which can also be limited. Moreover, the verticality of the environment causes many rockfalls that injure or kill the trees. Juniperus phoenicea which colonize these very restrictive habitat respond to the pressure of such a medium by a very low growth rate, a partial mortality of the aerial system and the cambium, the leaf morphological characteristics adapted to the drought, the ability to use water from mists and small rains that only wet the foliage, and they also have arbuscular mycorrhizal fungal community adapted to this environment, while at the same time achieving exceptional longevity.

Absorption foliaire d’eau

Bassin méditerranéen

Cernes

Contraintes hydriques

Escarpements rocheux

Longévité

Morphologie

Mortalité partielle du cambium

Structure de population

Foliar water absorption

Mediterranean basin

Rings

Water stress

Rocky escarpments

Longevity

Morphology

Partial mortality of cambium

Population structure