Structural and metamorphic evolution of the west-central Newton window, eastern Inner Piedmont, Burke, Catawba, and Lincoln Counties, North Carolina

Gilliam, William George

01 August 2010

Rocks of the western and eastern Inner Piedmont, along with the eastern Blue Ridge, comprise the Neoacadian metamorphic core of the southern Appalachians. The composite Inner Piedmont consists of the eastern Tugaloo (western Inner Piedmont) and Cat Square (eastern Inner Piedmont) terranes, which are separated by the Brindle Creek fault. Geochronologic evidence established the Brindle Creek fault as a terrane boundary within the Inner Piedmont, separating terranes of Laurentian and mixed Laurentian/Avalonian (peri-Gondwanan) zircon suites. The Newton window exposes Tugaloo terrane rocks of the Tallulah Falls Formation in the footwall of the Brindle Creek thrust sheet. Detailed geologic mapping in the western Newton window revealed structural and metamorphic similarities between rocks across the Brindle Creek fault. Peak metamorphism occurred contemporaneously with peak deformation, reaching upper amphibolite facies across both terranes. Peak Neoacadian metamorphism occurred between 360 and 345 Ma. Electron microprobe analyses of Cat Square terrane core and rim garnet-biotite and garnet-plagioclase pairs indicate an average temperature and pressure of 620 C, 3.6 kbar and 710 C, 6.1 kbar, respectively. Temperature and pressure estimates from the lower Tallulah Falls Formation core and rim analyses yield conditions of 570 C, 4.1 kbar and 690 C, 5.9 kbar, respectively. The maximum burial depth for both Cat Square and Tugaloo terrane rocks is ~20 km. The range in metamorphic ages suggests subduction and accretion occurred at a rate of 1 kilometer per 1.75 million years. Six deformational events shaped the western Newton window. D1 features are limited to amphibolite boudins of the Tugaloo terrane. D2 regional penetrative structures such as high-temperature foliations, mineral stretching lineations, and curved fold axes are the product of Neoacadian tectonism. The dominant S2 foliation trends north-northwest and dips moderately to the west-southwest. North-northwest-trending L2 mineral lineations parallel F2 fold axes, creating a curved map pattern recording crustal flow in an ancient orogenic channel. D3 resulted in open folding. The D4 event produced regional open folds. D5 and D6 features occur as joints, cataclasis, and diabase intrusion.

Strucutral geology

Inner Piedmont

Newton window

Tectonics and Structure

Tectonic evolution of the southern Appalachian Inner Piedmont: Identification and interpretation of crustal features from aeromagnetic data and detailed geologic mapping in central Georgia

Davis, Brittany Allison

01 May 2010

The Inner Piedmont (IP) is the Neoacadian migmatitic orogenic core of the southern Appalachians, exhibiting the widest area of high-grade metamorphism; regional upper amphibolite facies with isolated pods of granulite grade metamorphism. Peak P-T conditions in central GA reached 4.0-7.6 kbars and 630-715 ̊ C. The Brindle Creek fault (BCf) separates high-grade metasedimentary rocks of the eastern Tugaloo terrane (Tt) and Cat Square terrane (CSt). The Tt consists of the Neoproterozoic to early Paleozoic(?) Tallulah Falls Formation, Chauga River Formation, and the Mid-Ordovician Poor Mountain Formation, intruded by Early to Middle Ordovician granitoids. The CSt consists of Siluro-Devonian metasedimentary rocks, such as sillimanite-schist, biotite gneiss, amphibolite, and minor calc-silicate, intruded by Acadian-Neoacadian plutons. Original termination of the CSt was mapped by the USGS just south of Athens, GA, against the central Piedmont suture; however, new evidence from aeromagnetic anomalies and detailed geologic mapping revealed that the CSt and BCf extend into central GA. The BCf truncates a suite of curved magnetic anomalies on the aeromagnetic map. The curved anomalies that truncate against the linear feature may represent the Neoacadian deflection of the IP southwestward along the crustally weak Brevard fault zone. Another prominent lineament was identified southeast of the BCf; detailed geologic mapping revealed an additional thrust sheet in the CSt. Mesozoic brittle reactivation of the late Paleozoic dextral Towaliga fault was also identified striking NE-SW through the field area. Multiple episodes of movement were observed in outcrop and at the micro-scale, defined by crosscutting fracture sets. Low temperature quartz mylonite (350-450 ̊ C) may signify continued shearing of the IP into the late Alleghanian orogeny. A felsic plutonic suite extends the length of the field area, consisting of three distinct granitoids: (1) an older biotite-rich megacrystic granite with megacrysts of K-feldspar; (2) a weakly foliated medium to coarse grained inequigranular granodiorite; and (3) a younger non-foliated fine-grained granodiorite. Analysis revealed that granitoids from central GA are similar texturally and petrographically with granitoids from NC’s CSt. Further whole-rock geochemical analysis revealed that these rocks share similar REE, trace element, and tectonic discriminate patterns. The most important point garnered from the trace element and REE patterns in spider diagrams, such as similarities in peaks and troughs, is that they must share either a common parent, process, or contaminant.

Inner Piedmont

central Georgia

Brindle Creek fault

Rex Haven fault

Cat Square terrane

Siliceous Cataclasite

Towaliga fault

Geology

Tectonic evolution of the southern Appalachian Inner Piedmont: Identification and interpretation of crustal features from aeromagnetic data and detailed geologic mapping in central Georgia

Davis, Brittany Allison

01 May 2010

The Inner Piedmont (IP) is the Neoacadian migmatitic orogenic core of the southern Appalachians, exhibiting the widest area of high-grade metamorphism; regional upper amphibolite facies with isolated pods of granulite grade metamorphism. Peak P-T conditions in central GA reached 4.0-7.6 kbars and 630-715 ̊ C. The Brindle Creek fault (BCf) separates high-grade metasedimentary rocks of the eastern Tugaloo terrane (Tt) and Cat Square terrane (CSt). The Tt consists of the Neoproterozoic to early Paleozoic(?) Tallulah Falls Formation, Chauga River Formation, and the Mid-Ordovician Poor Mountain Formation, intruded by Early to Middle Ordovician granitoids. The CSt consists of Siluro-Devonian metasedimentary rocks, such as sillimanite-schist, biotite gneiss, amphibolite, and minor calc-silicate, intruded by Acadian-Neoacadian plutons. Original termination of the CSt was mapped by the USGS just south of Athens, GA, against the central Piedmont suture; however, new evidence from aeromagnetic anomalies and detailed geologic mapping revealed that the CSt and BCf extend into central GA. The BCf truncates a suite of curved magnetic anomalies on the aeromagnetic map. The curved anomalies that truncate against the linear feature may represent the Neoacadian deflection of the IP southwestward along the crustally weak Brevard fault zone. Another prominent lineament was identified southeast of the BCf; detailed geologic mapping revealed an additional thrust sheet in the CSt. Mesozoic brittle reactivation of the late Paleozoic dextral Towaliga fault was also identified striking NE-SW through the field area. Multiple episodes of movement were observed in outcrop and at the micro-scale, defined by crosscutting fracture sets. Low temperature quartz mylonite (350-450 ̊ C) may signify continued shearing of the IP into the late Alleghanian orogeny.A felsic plutonic suite extends the length of the field area, consisting of three distinct granitoids: (1) an older biotite-rich megacrystic granite with megacrysts of K-feldspar; (2) a weakly foliated medium to coarse grained inequigranular granodiorite; and (3) a younger non-foliated fine-grained granodiorite. Analysis revealed that granitoids from central GA are similar texturally and petrographically with granitoids from NC’s CSt. Further whole-rock geochemical analysis revealed that these rocks share similar REE, trace element, and tectonic discriminate patterns. The most important point garnered from the trace element and REE patterns in spider diagrams, such as similarities in peaks and troughs, is that they must share either a common parent, process, or contaminant.

Inner Piedmont

central Georgia

Brindle Creek fault

Rex Haven fault

Cat Square terrane

Siliceous Cataclasite

Towaliga fault

Geology