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Journal Article

Provenance of the Meguma terrane, Nova Scotia: rifted margin of early Paleozoic Gondwana Available to Purchase

John W.F. Waldron, Chris E. White, Sandra M. Barr, Antonio Simonetti, Larry M. Heaman
Published: 02 March 2009
Canadian Journal of Earth Sciences (2009) 46 (1): 1–8.
DOI: https://doi.org/10.1139/E09-004
...John W.F. Waldron; Chris E. White; Sandra M. Barr; Antonio Simonetti; Larry M. Heaman Abstract Detrital zircon ages from the lower part of the Late Proterozoic(?) to Middle Cambrian Goldenville Group in the Meguma terrane of Nova Scotia suggest derivation from local sources in the Avalonian and Pan...
View PDF for article title, Provenance of the Meguma terrane, Nova Scotia: rifted margin of early Paleozoic Gondwana
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Book Chapter

Lithochemistry of the Lower Paleozoic Goldenville and Halifax groups, southwestern Nova Scotia, Canada: Implications for stratigraphy, provenance, and tectonic setting of the Meguma terrane Available to Purchase

Author(s)
Chris E. White, Sandra M. Barr
Book: From Rodinia to Pangea: The Lithotectonic Record of the Appalachian Region
Publisher: Geological Society of America
Published: 01 September 2010
DOI: 10.1130/2010.1206(15)
... been redefined. The traditional twofold division into the meta-sandstone–dominated Goldenville Group and the overlying slate-dominated Halifax Group is retained, but the Chebogue Point shear zone divides these groups into western and southern stratigraphic packages containing different formations...
Abstract
View PDF for content titled, Lithochemistry of the Lower Paleozoic <span class="search-highlight">Goldenville</span> and Halifax <span class="search-highlight">groups</span>, southwestern Nova Scotia, Canada: Implications for stratigraphy, provenance, and tectonic setting of the Meguma terrane
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Add to Citation Manager for Lithochemistry of the Lower Paleozoic <span class="search-highlight">Goldenville</span> and Halifax <span class="search-highlight">groups</span>, southwestern Nova Scotia, Canada: Implications for stratigraphy, provenance, and tectonic setting of the Meguma terrane

Meguma, the most outboard northern Appalachian terrane, is characterized by Upper Neoproterozoic to Lower Ordovician turbiditic rocks that have an exposed thickness of more than 11 km. As a result of geological mapping, combined with petrological studies, the stratigraphy of these rocks has been redefined. The traditional twofold division into the meta-sandstone–dominated Goldenville Group and the overlying slate-dominated Halifax Group is retained, but the Chebogue Point shear zone divides these groups into western and southern stratigraphic packages containing different formations. In both packages, psammitic rocks are dominantly feldspathic wacke, and they have mineralogical compositions indicative of deposition in an active margin from a source dominated by quartz and plagioclase; rare conglomeratic units contain mainly psammitic clasts with some mafic through felsic volcanic clasts, and rare tonalite clasts. In the southern area, psammitic units tend to contain more quartz and grade to arenite. Although fine material increases in relative abundance, little change in provenance up section is indicated by petrography of psammitic rocks. Chemical compositions of 116 psammitic and pelitic samples from the western area and 471 from the larger southern area are consistent with the petrographic data. Their compositions are indicative of derivation from felsic to intermediate igneous material, and the depositional environment was probably in a rift along the Gond wanan margin. It is likely that Pan-African orogenic belts containing recycled sediments from older cratons were major contributors to the sediments, rather than sediments being derived directly from large ancient cratonic areas.

Journal Article

TEXTURE AND COMPOSITION OF GARNET AS A GUIDE TO CONTAMINATION OF GRANITOID PLUTONS: AN EXAMPLE FROM THE GOVERNOR LAKE AREA, MEGUMA TERRANE, NOVA SCOTIA Available to Purchase

Kara-Lynn Scallion, Rebecca A. Jamieson, Sandra M. Barr, Chris E. White, Saskia Erdmann
Published: 01 April 2011
The Canadian Mineralogist (2011) 49 (2): 441–458.
DOI: https://doi.org/10.3749/canmin.49.2.441
... groups. Garnet is abundant in the Beaverbank Formation of the Goldenville Group and its enclaves in the granitoid rocks. Single crystals of garnet, locally up to 3 cm in diameter, are also present in the Twin Lakes granodiorite and Bog Island Lake tonalite. On the basis of petrographic examination...
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View PDF for article title, TEXTURE AND COMPOSITION OF GARNET AS A GUIDE TO CONTAMINATION OF GRANITOID PLUTONS: AN EXAMPLE FROM THE GOVERNOR LAKE AREA, MEGUMA TERRANE, NOVA SCOTIA
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Journal Article

Cambrian–Ordovician acritarchs in the Meguma terrane, Nova Scotia, Canada: Resolution of early Paleozoic stratigraphy and implications for paleogeography Available to Purchase

C.E. White, T. Palacios, S. Jensen, S.M. Barr
Journal: GSA Bulletin
Published: 01 November 2012
GSA Bulletin (2012) 124 (11-12): 1773–1792.
DOI: https://doi.org/10.1130/B30638.1
...C.E. White; T. Palacios; S. Jensen; S.M. Barr Abstract Organic-walled microfossils (acritarchs) provide age constraints for the previously poorly dated Cambrian and Lower Ordovician turbiditic Goldenville and Halifax Groups in the northern Appalachian Meguma terrane of Nova Scotia and address...
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View PDF for article title, Cambrian–Ordovician acritarchs in the Meguma terrane, Nova Scotia, Canada: Resolution of early Paleozoic stratigraphy and implications for paleogeography
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Laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) traverses on low and high metamorphic grade samples from the Meguma and Bendigo-Ballarat terranes showing the distribution of selected elements. Meguma Terrane: (A) Regionally metamorphosed lower greenschist facies Goldenville Group argillite (MG3). Upper image shows the entire LA-ICP-MS traverse, lower image (SEM) shows a selected area through which the laser traverse passed, with the rutile grain transect highlighted on both the upper and lower image. (B) Regionally metamorphosed upper greenschist facies Goldenville Group psammite (MG-7). Upper image shows the entire LA-ICP-MS traverse, lower image (SEM) shows a selected area through which the laser traverse passed, with the ilmenite grain transect highlighted on both the upper and lower image. Bendigo-Ballarat Terrane: (C) Regionally metamorphosed lower greenschist facies Castlemaine Group argillite/psammite (NBD005-140.1). Upper image shows the entire LA-ICP-MS traverse, lower image (SEM) shows a selected area through which the laser traverse passed, with the rutile grain transect highlighted on both the upper and lower images. (D) Hornfelsed (well above the biotite-in isograd) Castlemaine Group psammite (H8). Upper image shows the entire LA-ICP-MS traverse, lower image (SEM) shows a selected area through which the laser traverse passed, with the ilmenite grain transect highlighted on both the upper and lower images. Abbreviations: Rt - rutile, Ilm - ilmenite, GG - Goldenville Group, CG - Castlemaine Group.

Laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) tra... Available to Purchase

Published: 30 November 2017
Goldenville Group argillite (MG3). Upper image shows the entire LA-ICP-MS traverse, lower image (SEM) shows a selected area through which the laser traverse passed, with the rutile grain transect highlighted on both the upper and lower image. (B) Regionally metamorphosed upper greenschist facies Goldenville
Image
Typical field appearance of comparable units in the Harlech Grits Group (left) and the lower part of the Meguma Supergroup (centre and right). (a) Typical Rhinog Formation; Harlech Castle, Gwynedd, Wales. (b) Close-up of (a) showing graded sandstone beds and interbedded cleaved mudstone. (c) Hafotty Formation, Barmouth, Gwynedd, Wales; thinly bedded manganiferous mudstone and sandstone cut by burrows. (d) Gamlan Formation cleaved mudstone and sandstone, Barmouth, Gwynedd, Wales. (e) Typical medium- to thick-bedded turbidites of Goldenville Group, Taylors Head Formation, Taylors Head, Nova Scotia. (f) Thin-bedded turbidites of Government Point Formation, upper Goldenville Group, Big Tancook Island, Nova Scotia. (g) Manganiferous mudstone with bedding largely obliterated by bioturbation; Government Point Formation, Big Tancook Island, Nova Scotia. (h) View of approximate bedding surface showing burrows preserved in manganoan carbonate and pyrite; prominent lineation is trace of cleavage; Government Point Formation, Big Tancook Island, Nova Scotia. (i) Medium- to thick-bedded turbidites of upper Government Point Formation; ruler lies on bed from which trilobite fragments were recovered by Pratt &amp; Waldron (1991); Big Tancook Island, Nova Scotia.

Typical field appearance of comparable units in the Harlech Grits Group (le... Available to Purchase

Published: 01 January 2011
mudstone. ( c ) Hafotty Formation, Barmouth, Gwynedd, Wales; thinly bedded manganiferous mudstone and sandstone cut by burrows. ( d ) Gamlan Formation cleaved mudstone and sandstone, Barmouth, Gwynedd, Wales. ( e ) Typical medium- to thick-bedded turbidites of Goldenville Group, Taylors Head Formation
Image
Scanning electron images of mineralogical textures within the Meguma (A–M) and Bendigo-Ballarat terranes (N–R). Meguma Terrane: (A) Heavy-mineral band (highlighted) in lower greenschist facies Halifax Group slate (CUN-03A) containing zircon, rutile, apatite, and other minerals. (B) Anhedral poikilitic rutile grain containing inclusions of muscovite, chlorite, and quartz in regionally metamorphosed lower greenschist facies Halifax Group psammite (CUN-13A). (C) Rounded rutile grain within regionally metamorphosed lower greenschist facies Halifax Group slate (CUN-03A). Rounded rutile grain displaying prominent zonation patterns under SEM; zonation is truncated by the rounded grain boundaries. (D) Rounded anhedral slightly poikilitic rutile grain, with subhedral to euhedral fine laths adjoining it, within regionally metamorphosed lower greenschist facies Halifax Group slate (CUN-03A). (E) Rounded slightly poikilitic rutile grain, with very minor subhedral to euhedral rutile laths adjoining it, within regionally metamorphosed lower greenschist facies Halifax Group slate (CUN-03A). Prominent zonation patterns are observed under SEM, with zonation being truncated by the rounded grain boundaries. (F) Polycrystalline rutile mantling quartz and pyrrhotite in regionally metamorphosed lower greenschist facies Halifax Group psammite (CUN-13B). (G) Subhedral poikilitic rutile grain containing inclusions of muscovite, chlorite, and quartz, in regionally metamorphosed lower greenschist facies Goldenville Group psammite/argillite (MG-3). (H) Anhedral poikilitic ilmenite grain containing inclusions of muscovite and quartz, and mantled by biotite, in regionally metamorphosed upper greenschist facies Goldenville Group psammite (MG-7). (I) Rotated subhedral poikilitic ilmenite grain containing inclusions of muscovite, chlorite, biotite, and quartz, in regionally metamorphosed upper greenschist facies Goldenville Group psammite (CUN-14A). Anhedral to subhedral rutile laths are observed along ilmenite grain boundaries. (J) Subhedral poikilitic ilmenite grain containing inclusions of muscovite, chlorite, biotite, and quartz in regionally metamorphosed upper greenschist facies Goldenville Group psammite (CUN-15D). Rare rutile relict grains are observed within some ilmenite grains and are texturally dissimilar to the commonly observed rutile laths that grow along ilmenite grain boundaries. Bendigo-Ballarat Terrane: (K) Rare heavy-mineral band (highlighted) in regionally metamorphosed lower greenschist facies Castlemaine Group psammite (259W1-798), containing zircon, rutile, apatite, and other minerals. (L) Enlargement of the heavy-mineral band shown in Figure 3K. (M) Rounded rutile grain within regionally metamorphosed lower greenschist facies Castlemaine Group psammite (NBD005-140.1). Rutile grains commonly display minor fracturing. (N) Subhedral rutile grain within regionally metamorphosed lower greenschist facies Castlemaine Group psammite (NBD005-140.1). Rutile grains commonly display rounding and minor fracturing. (O) Rare heavy-mineral band (highlighted) in hornfelsed (well above the biotite-in isograd) Castlemaine Group psammite (H8), containing zircon, apatite, ilmenite, and other minerals. (P) Band containing ilmenite and phyllosilicate minerals (e.g., muscovite and biotite) in hornfelsed (well above the biotite-in isograd) Castlemaine Group psammite (H9B). Not shown in this picture is that these bands run parallel to rare heavy-mineral bands (e.g., Fig. 3O). (Q) Ilmenite grains in hornfelsed (well above the biotite-in isograd) Castlemaine Group psammite (H9B). Ilmenite displays an intricate relationship to rutile. Rutile is most commonly observed along the edges of the ilmenite grains. (R) Enlargement of ilmenite displaying an intricate relationship to the rutile shown in Figure 3Q. Mineral abbreviations: Zrn - zircon, Rt - rutile, Ap - apatite, Cld - chloritoid, Ms - muscovite, Qtz - quartz, Po - pyrrhotite, Bt - biotite, Ilm - ilmenite. Fig 3. See preceding page for caption.

Scanning electron images of mineralogical textures within the Meguma (A–M) ... Available to Purchase

Published: 30 November 2017
Goldenville Group psammite/argillite (MG-3). (H) Anhedral poikilitic ilmenite grain containing inclusions of muscovite and quartz, and mantled by biotite, in regionally metamorphosed upper greenschist facies Goldenville Group psammite (MG-7). (I) Rotated subhedral poikilitic ilmenite grain containing
Image
Scanning electron images of mineralogical textures within the Meguma (A–M) and Bendigo-Ballarat terranes (N–R). Meguma Terrane: (A) Heavy-mineral band (highlighted) in lower greenschist facies Halifax Group slate (CUN-03A) containing zircon, rutile, apatite, and other minerals. (B) Anhedral poikilitic rutile grain containing inclusions of muscovite, chlorite, and quartz in regionally metamorphosed lower greenschist facies Halifax Group psammite (CUN-13A). (C) Rounded rutile grain within regionally metamorphosed lower greenschist facies Halifax Group slate (CUN-03A). Rounded rutile grain displaying prominent zonation patterns under SEM; zonation is truncated by the rounded grain boundaries. (D) Rounded anhedral slightly poikilitic rutile grain, with subhedral to euhedral fine laths adjoining it, within regionally metamorphosed lower greenschist facies Halifax Group slate (CUN-03A). (E) Rounded slightly poikilitic rutile grain, with very minor subhedral to euhedral rutile laths adjoining it, within regionally metamorphosed lower greenschist facies Halifax Group slate (CUN-03A). Prominent zonation patterns are observed under SEM, with zonation being truncated by the rounded grain boundaries. (F) Polycrystalline rutile mantling quartz and pyrrhotite in regionally metamorphosed lower greenschist facies Halifax Group psammite (CUN-13B). (G) Subhedral poikilitic rutile grain containing inclusions of muscovite, chlorite, and quartz, in regionally metamorphosed lower greenschist facies Goldenville Group psammite/argillite (MG-3). (H) Anhedral poikilitic ilmenite grain containing inclusions of muscovite and quartz, and mantled by biotite, in regionally metamorphosed upper greenschist facies Goldenville Group psammite (MG-7). (I) Rotated subhedral poikilitic ilmenite grain containing inclusions of muscovite, chlorite, biotite, and quartz, in regionally metamorphosed upper greenschist facies Goldenville Group psammite (CUN-14A). Anhedral to subhedral rutile laths are observed along ilmenite grain boundaries. (J) Subhedral poikilitic ilmenite grain containing inclusions of muscovite, chlorite, biotite, and quartz in regionally metamorphosed upper greenschist facies Goldenville Group psammite (CUN-15D). Rare rutile relict grains are observed within some ilmenite grains and are texturally dissimilar to the commonly observed rutile laths that grow along ilmenite grain boundaries. Bendigo-Ballarat Terrane: (K) Rare heavy-mineral band (highlighted) in regionally metamorphosed lower greenschist facies Castlemaine Group psammite (259W1-798), containing zircon, rutile, apatite, and other minerals. (L) Enlargement of the heavy-mineral band shown in Figure 3K. (M) Rounded rutile grain within regionally metamorphosed lower greenschist facies Castlemaine Group psammite (NBD005-140.1). Rutile grains commonly display minor fracturing. (N) Subhedral rutile grain within regionally metamorphosed lower greenschist facies Castlemaine Group psammite (NBD005-140.1). Rutile grains commonly display rounding and minor fracturing. (O) Rare heavy-mineral band (highlighted) in hornfelsed (well above the biotite-in isograd) Castlemaine Group psammite (H8), containing zircon, apatite, ilmenite, and other minerals. (P) Band containing ilmenite and phyllosilicate minerals (e.g., muscovite and biotite) in hornfelsed (well above the biotite-in isograd) Castlemaine Group psammite (H9B). Not shown in this picture is that these bands run parallel to rare heavy-mineral bands (e.g., Fig. 3O). (Q) Ilmenite grains in hornfelsed (well above the biotite-in isograd) Castlemaine Group psammite (H9B). Ilmenite displays an intricate relationship to rutile. Rutile is most commonly observed along the edges of the ilmenite grains. (R) Enlargement of ilmenite displaying an intricate relationship to the rutile shown in Figure 3Q. Mineral abbreviations: Zrn - zircon, Rt - rutile, Ap - apatite, Cld - chloritoid, Ms - muscovite, Qtz - quartz, Po - pyrrhotite, Bt - biotite, Ilm - ilmenite. Fig 3. See preceding page for caption.

Scanning electron images of mineralogical textures within the Meguma (A–M) ... Available to Purchase

Published: 30 November 2017
Goldenville Group psammite/argillite (MG-3). (H) Anhedral poikilitic ilmenite grain containing inclusions of muscovite and quartz, and mantled by biotite, in regionally metamorphosed upper greenschist facies Goldenville Group psammite (MG-7). (I) Rotated subhedral poikilitic ilmenite grain containing
Image
The South Mountain Batholith (SMB). Rocks of the Meguma Supergroup of southwestern Nova Scotia (inset) form the bulk of pre-batholith wallrocks. Rocks of the Halifax Group are dominantly pelitic compositions; rocks of the Goldenville Group are largely psammitic. Note the location of the Tangier Dike and northern SMB sample locations. HP: Halifax pluton. Geology after MacDonald (2001).

The South Mountain Batholith (SMB). Rocks of the Meguma Supergroup of south... Available to Purchase

Published: 01 April 2011
F ig . 1. The South Mountain Batholith (SMB). Rocks of the Meguma Supergroup of southwestern Nova Scotia (inset) form the bulk of pre-batholith wallrocks. Rocks of the Halifax Group are dominantly pelitic compositions; rocks of the Goldenville Group are largely psammitic. Note the location
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Fig. 1.

Regional geology map of Meguma terrane in central and southwestern Nova Sco... Available to Purchase

Published: 21 September 2015
Fig. 1. Regional geology map of Meguma terrane in central and southwestern Nova Scotia showing location of Late Ordovician to Early Devonian Rockville Notch Group overlying the Early Cambrian to Early Ordovician Halifax and Goldenville groups. The zones of reworked Neoacadian folds
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Simplified summary of tectono-stratigraphic relationships of various tectonic elements in the Canadian Appalachians (modified after van Staal 2007). Note that rifting and separation from Gondwana becomes progressively younger from Ganderia to Meguma. AG, Arisaig Group; DP, Dunn Point volcanic rocks; G, Goldenville Group; H, Halifax Group; MDG, Mount Douglas (Mohammadi et al. 2020); AG, Ackley Granite (Kellett et al. 2014); RNG, Rockville Notch Group (White et al. 2018); SMB, South Mountain batholith. [Colour online.]

Simplified summary of tectono-stratigraphic relationships of various tecton... Open Access

Published: 08 March 2022
volcanic rocks; G, Goldenville Group; H, Halifax Group; MDG, Mount Douglas ( Mohammadi et al. 2020 ); AG, Ackley Granite ( Kellett et al. 2014 ); RNG, Rockville Notch Group ( White et al. 2018 ); SMB, South Mountain batholith. [Colour online.]
Image
Relative probability density plots of: (A) compiled xenocrystic zircons in the South Mountain Batholith from this study; (B) metavolcanic zircon in the Silurian Rockville Notch Group (White et al. 2018); (C) detrital zircon studies from various formations that comprise the Goldenville Group in the Meguma terrane (cf. Krogh and Keppie 1990; Waldron et al. 2009; Pothier et al. 2015); and (D) detrital and metamorphic zircon in granulite xenoliths from the Pope's Harbour dyke (Shellnutt et al. 2019). [Colour online.]

Relative probability density plots of: (A) compiled xenocrystic zircons in ... Open Access

Published: 08 March 2022
Fig. 15. Relative probability density plots of: (A) compiled xenocrystic zircons in the South Mountain Batholith from this study; (B) metavolcanic zircon in the Silurian Rockville Notch Group ( White et al. 2018 ); (C) detrital zircon studies from various formations that comprise the Goldenville
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Trace-element concentrations of detrital rutile and metamorphic ilmenite in the Halifax Group (HG), Goldenville Group (GG), and Castlemaine Group (CG) as determined by LA-ICP-MS analyses. BDL values were replaced with half-detection limit values when calculating the mean, if greater than half of the data are above detection limit. Images show the range between the minimum and maximum values, the mean value (solid lines). Calculation of the mean for some elements (for example, Hf, Cr, and Mn) in rutile and ilmenite was not possible, as greater than half the data are BDL.

Trace-element concentrations of detrital rutile and metamorphic ilmenite in... Available to Purchase

Published: 30 November 2017
Fig. 5. Trace-element concentrations of detrital rutile and metamorphic ilmenite in the Halifax Group (HG), Goldenville Group (GG), and Castlemaine Group (CG) as determined by LA-ICP-MS analyses. BDL values were replaced with half-detection limit values when calculating the mean, if greater than
Image
(a) Geological map of the Meguma Zone of southwestern Nova Scotia, Canada. The South Mountain Batholith (SMB), and other late Devonian peraluminous granitoid rocks, are largely in contact with the metapelite-dominated Halifax Group (HG) and the metapsammite-dominated Goldenville Group (GG) of the Meguma Supergroup. The rectangle encloses the study area. (b) The study area along the northeastern margin of the SMB. For reasons of exposure, we mainly sampled road cuts, quarries, and construction sites. All SMB sulfides studied have a biotite granodiorite (Gd) host, whereas all MSG sulfides studied are from the Halifax Group (HG).

(a) Geological map of the Meguma Zone of southwestern Nova Scotia, Canada. ... Available to Purchase

Published: 01 October 2009
F ig . 1. (a) Geological map of the Meguma Zone of southwestern Nova Scotia, Canada. The South Mountain Batholith (SMB), and other late Devonian peraluminous granitoid rocks, are largely in contact with the metapelite-dominated Halifax Group (HG) and the metapsammite-dominated Goldenville Group
Image
Typical field appearance of comparable units in the upper Harlech Grits and Mawddach Groups (left) and the upper Goldenville and Halifax Groups (centre and right). (a) Inclined burrow, Gamlan Formation, Barmouth, Gwynedd, Wales. (b) Laminated mudstones, Clogau Formation, 0.6 km east of Barmouth, Gwynedd, Wales. (c) Siltstone (orange) and cleaved mudstone (black), Maentwrog Formation, 1 km east of Barmouth, Gwynedd, Wales. (d) Rippled siltstone and mudstone, Ffestiniog Fm.; 3 km SE of Porthmadog, Gwynedd, Wales. (e) Teichichnus spreite, Government Point Formation, Goldenville Group, Big Tancook Island, Nova Scotia. (f) Laminated manganiferous mudstone, Moshers Island Formation, Big Tancook Island, Nova Scotia. (g) Bedding surface view of mudstone showing circular manganoan mudstone concretions; Moshers Island Formation, Big Tancook Island, Nova Scotia. Prominent lineation is trace of cleavage. (h) Siltstone (orange) and cleaved mudstone (black) of Cunard Formation, ‘The Ovens', Mahone Bay, Nova Scotia. (i) Ripple cross-laminated siltstone (white) and cleaved mudstone (grey) of Feltzen Formation, upper Halifax Group, Mahone Bay, Nova Scotia. (j) Steep U-shaped burrow (Arenicolites), Feltzen Formation; locality as (i).

Typical field appearance of comparable units in the upper Harlech Grits and... Available to Purchase

Published: 01 January 2011
Fig. 5. Typical field appearance of comparable units in the upper Harlech Grits and Mawddach Groups (left) and the upper Goldenville and Halifax Groups (centre and right). ( a ) Inclined burrow, Gamlan Formation, Barmouth, Gwynedd, Wales. ( b ) Laminated mudstones, Clogau Formation, 0.6 km east
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Fig. 1.

( a ) Regional setting of the Meguma terrane in the Canadian Appalachian Or... Available to Purchase

Published: 03 September 2013
); 7, Moly Brook (Mo); 8, Moly Hill (Mo); 9, Ackley Granite (Mo–Sn–W). Also, note location of Fig. 1 b . ( b ) Geological setting (after Horne et al. 2000 ) of the study area in the southwestern Meguma terrane. Geological units shown are the Cambro-Ordovician Goldenville (GG) and Halifax (HG) groups
Journal Article

40 Ar– 39 Ar ages for detrital white mica in Meguma terrane, Nova Scotia, Canada: implications for provenance of the Goldenville and Halifax groups Available to Purchase

P.H. Reynolds, C.E. White, S.M. Barr, C.M. Muir
Published: 19 June 2012
Canadian Journal of Earth Sciences (2012) 49 (7): 781–795.
DOI: https://doi.org/10.1139/e2012-022
...P.H. Reynolds; C.E. White; S.M. Barr; C.M. Muir Abstract Single-grain 40 Ar/ 39 Ar ages are reported for detrital white mica, along with conventional step-heating data for whole rocks, from low-grade metasandstone samples from the Goldenville, Halifax, and Rockville Notch groups in the Meguma...
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View PDF for article title, 40 Ar– 39 Ar ages for detrital white mica in Meguma terrane, Nova Scotia, Canada: implications for provenance of the <span class="search-highlight">Goldenville</span> and Halifax <span class="search-highlight">groups</span>
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Image
Typical grains of rutile from the Meguma Supergroup country rocks, and from xenolithic samples within the SMB. (a) Ovoid, poikilitic grain of rutile (sample 101–2) in a fine-grained matrix composed of chlorite and muscovite from a sandy layer in the Halifax Group. (b) Lath-shaped, poikilitic grain of rutile (sample 109d–6) from a slaty layer in the Halifax Group. (c) Poikilitic grain of coexisting ilmenite and rutile (also from sample 109d–6). (d) Subhedral, poikilitic grain of coexisting ilmenite, rutile, and titanite (sample 9b–x) from a slaty layer in the Goldenville Group. (e) Rutile grain showing a symplectitic intergrowth texture with silicates in a xenolith (sample E436G–18). (f) Rutile grain showing a symplectitic intergrowth texture with titanite in a xenolith (sample E431B–6).

Typical grains of rutile from the Meguma Supergroup country rocks, and from... Available to Purchase

Published: 01 June 2006
, poikilitic grain of rutile (sample 109d–6) from a slaty layer in the Halifax Group. (c) Poikilitic grain of coexisting ilmenite and rutile (also from sample 109d–6). (d) Subhedral, poikilitic grain of coexisting ilmenite, rutile, and titanite (sample 9b–x) from a slaty layer in the Goldenville Group. (e
Journal Article

Does Tungsten Availability Control the Presence of Tungsten in Turbidite-hosted Orogenic Gold Mineralization? Evidence from the Meguma and Bendigo-ballarat Terranes Available to Purchase

Ben J. Cave, Ross R. Large, Chris E. White, Stafford McKnight
Published: 30 November 2017
The Canadian Mineralogist (2017) 55 (6): 973–999.
DOI: https://doi.org/10.3749/canmin.1600088
... Goldenville Group argillite (MG3). Upper image shows the entire LA-ICP-MS traverse, lower image (SEM) shows a selected area through which the laser traverse passed, with the rutile grain transect highlighted on both the upper and lower image. (B) Regionally metamorphosed upper greenschist facies Goldenville...
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Add to Citation Manager for Does Tungsten Availability Control the Presence of Tungsten in Turbidite-hosted Orogenic Gold Mineralization? Evidence from the Meguma and Bendigo-ballarat Terranes
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Representative photographs of field relationships shown by plutonic rocks in the eastern Meguma terrane: (a) sheared granite in the Canso plutonic suite; (b) relict bedding preserved in xenolith in the Canso plutonic suite including Mn coticules indicating xenolith derivation from the Beaver Bank Formation of the Goldenville Group (see Fig. 2 legend); (c) disaggregated xenoliths near the margin of the Canso plutonic suite; (d) representative porphyritic muscovite–biotite granite from the Canso plutonic suite; (e) large, zoned K-feldspar phenocrysts in the Queensport pluton; (f) contact between muscovite–biotite granite and biotite granite in the eastern Meguma terrane exposed in the Canso plutonic suite; (g) dioritic dyke with a foliated xenolith of pink muscovite–biotite granite from the Cranberry Lake pluton; (h) rounded, fine-grained enclaves of quartz diorite hosted in the coarser grained tonalite in the Trafalgar plutonic suite; and (i) tonalite mingled with granitic enclave (outlined in a dotted line) in the Garry Lakes pluton. The pen in a, d, and e is 15 cm. The hammer in b, c, and f is 35 cm.

Representative photographs of field relationships shown by plutonic rocks i... Available to Purchase

Published: 05 July 2024
the Beaver Bank Formation of the Goldenville Group (see Fig. 2 legend); ( c ) disaggregated xenoliths near the margin of the Canso plutonic suite; ( d ) representative porphyritic muscovite–biotite granite from the Canso plutonic suite; ( e ) large, zoned K-feldspar phenocrysts in the Queensport pluton