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Original Article

Cite this article: Kwayisi D, Nyavor E,
Dzikunoo EA, Fynn IEM, Kutu J, and Nude PM.
Cryogenian-Ediacaran crustal growth and
evolution of the active margin of the
Dahomeyide belt, Ghana. Geological Magazine
https://doi.org/10.1017/S0016756823000808

Received: 19 September 2023
Revised: 1 December 2023
Accepted: 4 December 2023

Keywords:
crustal thickening; crustal anatexis; continent-
continent collision; migmatite; continental
subduction

Corresponding author:
Daniel Kwayisi; Email: danielk@uj.ac.za

© The Author(s), 2024. Published by Cambridge
University Press. This is an Open Access article,
distributed under the terms of the Creative
Commons Attribution licence (http://creativeco
mmons.org/licenses/by/4.0/), which permits
unrestricted re-use, distribution and
reproduction, provided the original article is
properly cited.

Cryogenian-Ediacaran crustal growth and
evolution of the active margin of the
Dahomeyide belt, Ghana

Daniel Kwayisi1,2 , Emmanuel Nyavor2, Elikplim Abla Dzikunoo2,

Iris Ekua Mensimah Fynn3, Jacob Kutu2 and Prosper M Nude2

1Department of Geology, University of Johannesburg, Auckland Park Kingsway Campus, South Africa; 2Department
of Earth Science, University of Ghana, Legon-Accra, Ghana and 3Department of Geography and Resource
Development, University of Ghana, Legon-Accra, Ghana

Abstract

The study presents detailed petrographical, geophysical, structural and geochemical data of the
internal nappes zone to establish the deformational history, origin and tectonic setting and
constrain the crustal growth and evolution of the active margin of the Dahomeyide belt. Two
main lithological units, (i) deformed meta-granitoids (migmatites and gneisses) and
(ii) undeformed granitoids, dominate the internal nappes zone. The granitoids are generally
I-type, metaluminous to weakly peraluminous, low-K tholeiite to high-K calc-alkaline and of
tonalite, granodiorite and granite affinity. The overall trace element patterns of the studied
granitoids characterized by the enriched LILE and depleted HFS, with negative peaks of Nb-Ta,
Sr, P and Ti, are indications of arc-related magmatism. Structural analysis reveals four
deformation phases (D1-D4). D1 represents Northwest-Southeast (NW-SE) Pan African
shortening associated with a continent-continent collision, resulting in westward nappe
stacking. Progressive NW-SE shortening resulted in D2 and D3 top-to-the-NW dextral and
sinistral thrusting events during the Pan-African orogeny. D4 is an extensional event likely
associated with the orogenic collapse phase. The gneisses and migmatites, with dominant axial
planar foliations, point to their formation in a collisional setting or influence by the Pan-African
collisional processes. Continental-arc signatures in these rocks imply continental subduction
during their protolith formation. The intrusive granitoid and pegmatite are undeformed,
meaning late- to post-orogenic emplacement. These findings suggest that the internal nappes
zone archived the subduction-collision and post-collisional phase of the Pan-African orogeny
and recorded large-scale migmatization and granitoid emplacement due to partial melting of
thickened lower crust between Mid-Cryogenian and late Ediacaran.

1. Introduction

The Pan-African Dahomeyide belt occupying the southeastern margin of the West African
Craton records a complete orogenic cycle during the Cryogenian-Ediacaran period and consists
of features, including basement complex, passive margin, oceanic terrane and active margin
(arc-crust and post-collisional basins) (Figure 1(a) and (b); Attoh and Nude, 2008; Attoh
et al. 2013; Aidoo et al. 2021; Kwayisi et al. 2022a). The Dahomeyide belt forms the central
segment of the West Gondwana Orogen (inset Figure 1(a)) and formed during the
subduction-collision phases of the Pan-African orogeny (Attoh and Nude, 2008; Guillot
et al. 2019; Aidoo et al. 2021). Based on lithology and tectonics, this belt has been divided
into an internal nappes zone, suture zone and external nappes zones (Duclaux et al. 2006;
Attoh and Nude, 2008; Kwayisi et al. 2020). In a plate tectonic scenario, the upper and lower
plates of the Dahomeyide belt are represented by the internal and external nappes zones,
respectively (Figure 1(c)), and separated by a well-defined suture zone of ultrahigh pressure-
high pressure eclogite and granulite rocks (Figure 1(b) and (c); Attoh and Morgan, 2004;
Attoh and Nude, 2008). The internal nappes zone (Figure 1(b) and (c)) corresponds to the
active margin of the Dahomeyide belt that recorded arc-related and post-collisional
magmatism and intracontinental extensional volcanism and sedimentation during the Pan-
African orogeny (Kalsbeek et al. 2012; Attoh et al. 2013; Ganade de Araujo et al. 2016). The
internal nappes zone is made up of granitoids and supracrustal rocks formed due to the east-
dipping subduction and continent-continent collision between theWest African Craton and
the Benin-Nigerian Shield (BNS) and extensional-related volcanic and sedimentary rocks
formed after collision (e.g., Attoh and Nude 2008; Attoh et al. 2013; Ganade de Araujo et al.
2016; Guillot et al. 2019). The granitoids constitute the bulk of the internal nappes zone, with
the supracrustal and extensional-related rocks being only minor (Kalsbeek et al. 2012; Attoh
et al. 2013; Ganade de Araujo et al. 2016).

https://doi.org/10.1017/S0016756823000808 Published online by Cambridge University Press

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https://doi.org/10.1017/S0016756823000808
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https://doi.org/10.1017/S0016756823000808


Twomajor types of granitoids occur in the internal nappes zone
of the Dahomeyide belt. (i) migmatites, and (ii) gneisses (Table 1:
Attoh et al. 2013) intruded by granites and granodiorites (Kalsbeek
et al. 2012; Attoh et al. 2013). Kalsbeek et al. (2012) obtained U-Pb
zircon ages of 547 ± 15 Ma and 666 – 592 Ma for the intrusive
granitoids and the migmatites, respectively. Similarly, U-Pb ages of
620 – 589Ma have been obtained for the migmatites by Attoh et al.
(2013). The 589 – 547 Ma age corresponds to post-collisional
magmatism, with the 666 – 620 Ma corresponding to arc-related
magmatism (Kalsbeek et al. 2012; Attoh et al. 2013; Ganade de
Araujo et al. 2016). These ages suggest an approximately 100 Ma
span of arc-related and post-collisional magmatism during the
Pan-African orogeny between Mid-Cryogenian at 670 and late
Ediacaran at 540 Ma (Kalsbeek et al. 2012).

Very little is known about the structural evolution of the
granitoids of the internal nappes zone (i.e., active margin) of the
Dahomeyide belt in Ghana. Hence, it becomes difficult to interpret
the tectonic evolution of these units in relation to the Pan-African
orogeny. However, elsewhere in the Parakou-Nikki region of
northern Benin, five deformational phases have been interpreted
and linked to various stages of the Pan-African orogeny (Chala
et al. 2015). This work, therefore, seeks to shed light on the
structural evolution by integrating field, geophysical and structural
data of the Dahomeyide internal nappes zone and examine their
significance in the overall crustal growth and evolution of the
Dahomeyide belt and implications to the Pan-African orogeny.
Besides, there is no petrographical and geochemical data on
the post-collisional granitoids to constrain their source, tectonic

setting and petrogenetic evolution. Hence, the major and trace
element concentration of the post-collisional granitoids and
also new geochemical data of the arc-related granitoids (i.e., the
gneisses and migmatites) are presented to infer their source,
tectonic setting and petrogenetic evolution.

2. Geological setting

The internal nappes zone (i.e., active margin) of the Pan-African
Dahomeyide belt represents the south-western portion of the
Benin-Nigerian Shield, which is the south-western limit of the
Saharan metacraton (Figure 1(a); Abdelsalam et al. 2002; Chala
et al. 2015). The other zones of the Pan-African Dahomeyide belt
are the external and the suture zones (Guillot et al. 2019; Kwayisi
et al. 2020; 2022b). The external nappes zone represents the lower
plate, whereas the internal nappes zone is the upper plate of the
Pan-African Dahomeyide belt. The suture zone is the vestiges of
the Pharusian oceanic crust, formed during the Pan-African
oceanic accretionary phase (Duclaux et al., 2006; Attoh and
Morgan, 2004; Agbossoumondé et al. 2017; Kwayisi et al. 2022a).
The internal nappes zone occurs to the immediate east of the suture
zone, where they are separated by tectonic contacts (Figure 1(b)).
The internal nappes zone is made up of a complex of meta-
granitoid basement, underlying volcano-sedimentary Neoproterozoic
supracrustals, and invaded by several generations of arc-related Pan-
African and post-collisional granitoids (Table 1; Figure 1(b); Affaton
et al. 1991; Attoh et al. 2013; Ganade deAraujo et al. 2016). Attoh et al.
(2013) subdivided themeta-granitoid basement of the internal nappes

Figure 1. (Colour online) (a) Schematic geological map of theWest African Craton (insert is themap ofWest Gondwana Orogen; after Ganade de Araujo et al. 2016), (b) Geological
map of Dahomeyide belt (modified after Kwayisi et al. 2022b), (c) Cross-section of the Dahomeyide belt, showing the lower plate (i.e., external nappes zone, to the west), upper
plate (internal nappes zone (Active margin), to the east), separated by the suture zone (modified after Guillot et al. 2019).

2 D Kwayisi et al.

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zone into two, namely dioritic gneiss, characterized by hornblende as
the main mafic mineral and occasional garnet and migmatite with
biotite as the dominant mafic mineral (Table 1). U-Pb zircon ages of
666 – 620 Ma corresponding to arc-related magmatism have been
obtained for the migmatites (Figure 1(b); Kalsbeek et al. 2012;
Attoh et al. 2013; Ganade de Araujo et al. 2016). The migmatites
have been postulated as juvenile crust representing the arc
terrane that formed due to subduction and oceanic closure
during the Pan-African orogeny (Attoh et al. 2013). However,
older U-Pb zircon crystallization ages ranging from 2.14 to 2.19
Ga were recorded for the dioritic gneisses (Attoh et al. 2013).
The Paleoproterozoic ages signify the involvement of older crust
(Saharan Metacraton), representing the basement of the Benin-
Nigerian Shield, in the Pan-African Dahomeyide belt (Duclaux
et al. 2006; Attoh et al. 2013). The migmatites are intruded by
post-collisional granitoids dated at 589 – 547 Ma, correspond-
ing to post-collisional magmatism (Kalsbeek et al. 2012; Attoh
et al. 2013).

3. Field relations and petrography

Field observations and petrographical investigations reveal that
two main lithological units dominate the internal nappes zone of
southeastern Ghana. These are (i) deformed meta-granitoids made
up of migmatites and gneisses and (ii) undeformed granitoids,
herein referred to as intrusive granitoids composed dominantly of
granite and minor granodiorite. Amphibolite, pegmatite, aplite
and quartz veins also occur. Figure 2 is a geological map of
southeastern Ghana, showing the extent and distribution of the
rocks in the study area. The deformed meta-granitoids dominate
over the intrusive granitoids in terms of volume.Widespread in the
internal nappes zone are the migmatites (Figure 2).

In general, the migmatite consists of alternating leucosomes
and melanosomes, thus representing typical stromatic migmatite
(Figure 3(a)). The migmatite is coarse-grained and contains
microcline (45%), quartz (30%), plagioclase (15%), biotite (7%),

muscovite (2%) and garnet (1%), with epidote, titanite, zircon and
rutile as accessory minerals. This rock shows micro-folds defined
by bent quartz grains (Figure 3(b)). Myrmekites of K-feldspar in
plagioclase are present as small spots disseminated in some
plagioclases or invading K-feldspar and plagioclase from their
margins (Figure 3(c)). The gneisses are made up of felsic augen,
biotite and hornblende-biotite gneisses. The felsic augen gneiss
shows coarse-grained augen feldspars in a porphyroblastic texture
(Figure 3(d)). Generally, the rock appears light grey with a
porphyroblastic and myrmekite texture. It consists of quartz
(30%), plagioclase (25%), orthoclase (15%), microcline (15%),
biotite (12%), hornblende (2%) and sericite (1%) in a preferred
orientation (Figure 3(e)). The porphyroblasts are essentially
orthoclase. In contrast, biotite occurs as interstitial or inclusions
in orthoclase. Inclusions of quartz occur in the microcline and
orthoclase, while sericite occurs as inclusions or secondary
minerals in the plagioclase and microcline. The biotite gneiss
(Figure 3(f)) has a coarse-grain texture and well-defined foliations.
This rock consists of quartz (40%), microcline (25%), plagioclase
(20%), biotite (10%), muscovite (4%), sericite (1%) and accessory
phases, including titanite, zircon and garnet (Figure 3(g)). Garnet
contains inclusions of quartz and micro-fractures, filled with
elongate biotite. The hornblende-biotite gneiss has a coarse-grain
texture and a pale ash-grey colour (Figure 3(h)). It consists of
plagioclase (33%), quartz (20%), orthoclase (20%), biotite (15%),
hornblende (5%), microcline (3%), garnet (2%) and calcite (1%)
with accessory muscovite and epidote (Figure 3(i)). Inclusions of
quartz and muscovite occur in the plagioclase.

Within the internal nappes zone, but distinctly different from
the typical deformed migmatites and gneisses, are intrusive bodies
of granitic and granodioritic rocks (intrusive granitoids) with
sharp lithological boundaries with the migmatites and gneisses
(Figures 4(a) and (b)). They are distinguished by being typically
undeformed or only weakly deformed. The granite occurs as large
and massive bodies within the biotite gneiss (Figure 4(a)), whereas
the granodiorite occurs as a dyke within the migmatite and felsic

Table 1. Compiled lithological, metamorphic, P-T, age and tectonic data on the internal nappes zone of the Dahomeyide belt

Unit Metamorphism
P-T

condition
Crystallization/
depositional age

Metamorphic
age Setting

Granitoid gneiss and
migmatite*

Biotite bearing migmatite* Amphibolite
facies‡

” 666 – 592 Ma*,§

(U-Pb, zircon)
” Magmatic arc*

Hornblende ± garnet-
bearing dioritic gneiss*

2190–2140 Ma*,∥

(U-Pb, zircon)

Supracrustal rocks† Schist† ” ” 600 Ma† (U-Pb,
zircon, detrital)

” Foreland†

Migmatite† 660 Ma† (U-Pb,
zircon, detrital)

Quartzite†

Extensional volcanic and
sedimentary rocks†

Dacite† 545.7 ± 7.8 Ma†
(U-Pb, zircon)

Post collision
extensional rifting*

Conglomeratite† 563 ± 7 Ma† (U-Pb,
zircon, detrital)

*Attoh et al. (2013).
†Ganade de Araujo et al. (2016).
‡Nude (1995).
§Kalsbeek et al. (2012).
∥Kalsbeek et al. (2020).

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augen gneiss, generally oriented north-south and discordant to the
general foliations of the host rock (Figure 4(b)). The granite
(Figure 4(c)) is leucocratic, characterized by phaneritic texture, and
consists of microcline (45%), quartz (25%), plagioclase (20%),
biotite (6%), muscovite (2%), sericite (2%), epidote (1%) and
garnet occurring as accessory minerals. Micro-fractures occur in
the quartz, biotite inclusions in the microcline and quartz in
plagioclase. Muscovite and sericite are secondary minerals derived
from the alteration of feldspars. The granodiorite is medium to
coarse-grained with characteristic myrmekitic textures. It consists
of quartz (30%), plagioclase (25%), biotite (15%), orthoclase (12%),
hornblende (12%), calcite (4%) and microcline (2%) (Figure 4(d)).
Some of the quartz grains occur as minor fine inclusions in the
plagioclase, hornblende and biotite.

4. Structures and deformation

The structural elements of theDahomeyide internal nappes zone of
southeastern Ghana are characterized by four deformational
events (D1, D2, D3, and D4), which are well-developed in the
gneisses and migmatites. An earlier D1 phase formed NE-SW S1
foliations and asymmetric quartz porphyroblasts and was
associated with F1 isoclinal folds (Figures 5(a) and (b)). The plot
to poles for the S1 foliations also shows that the foliations generally
dip to the southeast and are concentrated closer to the sphere than
the centre and, therefore, indicate low tomoderate dip angles to the
southeastern direction (Figure 2).

D2 phase corresponds to the formation of S2 foliations (NW-SE
striking cleavages), F2 folds (drag folds), kink folds and coeval with
penetrative top-to-the-NW dextral (C-S fabrics) shear plane (C2)

Figure 2. (Colour online) Geological map of southeast
Ghana showing the lithological distribution and struc-
tural relationships of the rocks of the study area. Insert
are the pole to plane plots of the S1, S2 and S3 foliations.

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as well as the formation of older generational joints in the gneisses
and migmatites (Figures 2, 5(a) and (c)–(e)). The stereographic
projections (plot to pole) of these planes show a general
concentration close to the centre of the circle, indicating moderate
to high dips for the cleavages (Figure 2). The presence of kink folds
is also an indication of the high intensity of the D2 event. The D2

event also produced small-scale Z-shaped drag and parasitic folds.
D3 event is a shearing event with a top-to-the-NW sinistral (C-S

fabric) shear plane (C3; Figures 2 and 5(f))). These small-scale
faults are observed only in the migmatites and gneisses. The C3

shear fault planes generally strike in the NW-SE directions with
low to moderate dips to the southwest. The C3 faults displaced
S1 foliations, the C2 dextral shear faults, the F2 folds and the
older joints and developed the low NNE dipping S3 foliations
(Figure 2).

A final D4 event resulted in the formation of the younger
generational joint and fault planes striking in East-West (E-W)
and Northnorthwest-Southsoutheast (NNW-SSE) directions
(Figure 5(f)). The effects of this deformation are observed in the
aplite veins and granodiorite dyke.

Figure 3. (Colour online) Field photos and photomicro-
graphs of the gneisses and migmatite of the internal
nappes zone (a) Migmatite consists of alternating
leucosomes andmelanosomes, thus representing typical
stromatic migmatite, (b) Migmatite showing micro-folds
defined by bent quartz grains (crossed polars),
(c) Myrmekite texture invading microcline and plagio-
clase at their margins, (d) Felsic augen gneiss with
coarse-grained augen feldspars (crossed polars),
(e) Foliation in the felsic augen gneiss defined by
elongated quartz and biotite (crossed polars),
(f) Biotite gneiss with phaneritic texture and well-defined
foliations, (g) Foliation in biotite gneiss defined by biotite
minerals (crossed polars), (h) Hornblende-biotite gneiss
and (i) Hornblende-biotite gneiss with coarse hornblende
minerals (crossed polars). Bt = biotite, Grt = garnet, Hbl
= hornblende, Mc = microcline, Or = orthoclase, Pl =
plagioclase, Qz = quartz. Mineral abbreviation is from
Whitney and Evans (2010).

Figure 4. (Colour online) Field photos and photomicro-
graphs of the intrusive bodies of the internal nappes
zone. (a) Large intrusion of granite bodies into the biotite
gneiss, (b) Dykes of granodiorite within the migmatite
(c) Leucocratic granite characterized by phaneritic
texture (crossed polars) and (d) Granodiorite showing
medium to coarse-grained with characteristic myrme-
kitic textures (crossed polars).

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5. Geophysical data processing and interpretation

5.1. Geophysical data processing

The aeromagnetic geophysical survey data for the study area
was obtained from the Ghana Geological Survey Authority, Accra.
This data was acquired between February and November 1997
by the Geological Survey of Finland. The survey was flown in the
E-W direction with a nominal line separation set at 400 m and
a terrain clearance of 70 m. The data was grid using the
bi-directional gridding method because it strengthens trends
perpendicular to the survey line directions. The disadvantage,
however, is that tie-line data cannot be incorporated into the
interpolation method.

The total magnetic intensity grid (TMI) obtained from the
gridding was enhanced by applying appropriate filters such as
reduce to the equator (RTE), first vertical derivative (1VD), tilt
derivative (TD) and automatic gain control (AGC). The RTE
filter was applied on the TMI grid to reposition anomalies directly
over their sources (Milligan and Gunn, 1997; Kwayisi et al. 2020;
Dzikunoo et al. 2021). The RTE was chosen over the reduced to-
pole because of the study area’s low latitude position. An
inclination of −13.17 and a declination of −5.23 were applied
in the filtering; the final result was then inverted using a
multiplication factor of −1.

Akin to the RTE operation, the analytic signal (AS) centres
anomalies directly over causative bodies (Gunn, 1997). Additionally,
it is useful in lowmagnetic latitudes because of its independence from
ambient fields and the direction of source bodymagnetization (Gunn,
1997). Ridges or peaks in the AS-TMI anomaly map coincide with
faults, shear zones and lithological contacts. The 1VD filter was
applied to the RTE grid to enhance shallow geological structures by
accentuating short-wavelength (high wave-number) anomalies that
are caused by surface and near-surface geological bodies (Paine,
1986). The 1VD filter also enhances the edges of anomalies to
determine the boundaries of geological bodies easily. This filter allows
for the visualization of the change in the measured parameters as
distance to source (survey height) changes. It is ideal to perform the
1VD filter on the RTE-TMI grid because the outputwill show the zero

contour values directly over the edges of the magnetic source bodies
(Kwayisi et al. 2020; Dzikunoo et al. 2021).

The AGC and TD were applied on the RTE grid. The AGC
works to enhance minor structural trends, making them more
discernible. Its application works with some rescaling applications
to reduce the dynamic range of magnetic data to avoid substantial
anomalies and mask subtle anomalies. The TD, conversely, defines
the extent of the edges of the various sources (Oruc and Selim,
2011). The enhancement highlights short wavelengths. The
processed geophysical maps were opened in an ArcGIS environ-
ment for detailed interpretation. Geophysical maps were used to
identify lineaments, which include folds, faults and thrusts. This
was done by observing certain characteristics such as displacement
in a noticeable linear feature, a sudden change in amplitude,
duplication of magnetic signals, truncation of a primarily linear
magnetic domain by a curvilinear feature and a curved magnetic
pattern (Kwayisi et al. 2020).

5.2. Geophysical data interpretation

The TMImap shows a sort of division of magnetic intensities, with
the area to the north showing higher magnetic intensities than the
area to the south (Figure 6(a)). The RTE shows a similar
distribution of the magnetic signatures with a better definition of
some features. The RTE grid was then inverted (Figure 6(b)),
giving high anomalies the appropriate pink colour for straightfor-
ward interpretation and comparison. The general NE-SW feature
trend is likely related to the S1 NE-SW foliations observed on the
field (Figures 2, 6(a) and (b)).

The AS map and the RTE-inv both show a central NE-SW
trending region with high magnetic anomalies and traces of
structures (Figures 6(b) and (c)). The NNE-facing nose of a tight
chevron fold is seen at the southwesternmost end of the study area
andwithin the demarcated shear zone (Figure 6(d)). This is linked to
F1 folding event that resulted in the NE-SW S1 foliation. A major
thrust/shear plane runs through the central portion of the study area
(Figure 6(d)). The thrusting is observed as a repetition of the
magnetic anomalies. These observed thrust/shear depict top-to-the-

Figure 5. (Colour online) (a) Northeast-Southwest (NE-
SW) S1 foliations in the migmatite folded by F2 kink folds
(b) Quartz porphyroblasts showing top-to-the-NE shear-
ing, (c) F2 fold (drag folds), and penetrative top-to-the-
NW dextral (C-S fabrics) shear plane (C2) (d) Near
horizontal NW-dipping L2 stretching lineation, (e) C3
sinistral top-to-the-NW shear (C-S fabrics) planes with
generally NW-SE strike and (f) Late joints cutting through
the migmatite and some veins. Most of the outcrops
occur as platforms thus, features were viewed on the
horizontal surface.

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NWmovement and thusmay be associated with both dextral strike-
slip and sinistral strike-slip movement of D2 and D3 events. In fact,
observed dextral and sinistral fault plane falls within this zone
(Figure 2). The dextral strike-slip and sinistral strike-slipmovements
are thus, related to D2 and D3 deformational events that developed
the C2 and C3 shear planes, respectively, observed in the field
(Figure 5).

Lithologically, biotite gneiss and intrusive granitoid (granite
and granodiorite) rocks seem to occupy the shear zone with
some enclaves of garnet amphibole gneiss (Agyei-Duodu et al.
2009). These exhibit intermittent high and low magnetic
signatures in the mid-portion and southeastern corner of the
study area in the AGCmap (Figure 6(e)). Late dominantly NW-
SE striking and few E-W striking faults and joints are observed

Figure 6. (Colour online) (a) Total Magnetic Intensity map of the internal nappes zone of the Dahomeyide belt with NE-SW striking high and low magnetic intensities
corresponding to different geological terrains, (b) Inverted Reduced-to-the-equator map of the internal nappes zone, giving high anomalies the appropriate pink colour for
straightforward interpretation and comparison, (c) Analytic signal map that is useful in centring anomalies directly over causative bodies, and showing NE-SW trending
region with high magnetic anomalies and traces of structures and (d) First Vertical Derivative map showing major thrust faults as a result of cyclic map repetition of the
same magnetic signal. (e) Automatic gain control map exhibiting intermittent high and low magnetic signatures in the mid-portion and southeastern corner of the
study area. These correspond to biotite gneiss and intrusive granitoids, and (f) dominantly NW-SE striking and few E-W striking faults and joints are observed on the Tilt
derivative map.

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on the TD map (Figure 6(f)). These late faults and joints
correspond to the late D4 deformational event observed in
the field.

6. Geochemical characteristics

6.1. Analytical procedure

Representative samples of migmatites (3), gneisses (8), intrusive
granitoids (5) and pegmatite (1) were analyzed for major and trace
element concentrations at the ALS laboratory in Vancouver, Canada.
Analytical techniques followed the protocol of the procedures at the
ALS laboratory (see Kwayisi et al. 2017). The major and trace
elements analyses were carried out by Inductively Coupled Plasma-
Atomic Emission Spectrometry and multi-elements fusion
Inductively Coupled Plasma Mass Spectrometry, respectively.
Loss on ignition was determined at 1000°C. Elements with
concentration >1 wt. % recorded 1 – 3% analytical uncertainty,
whereas those in low concentrations (<1 wt. %) recorded
uncertainty of 10%. On the whole, precision was better than 5%.

6.2. Major and trace element concentrations

Major and trace element concentrations for representative samples
of the granitoids of the internal nappes zone (i.e, active margin) of
the Dahomeyide belt are presented in Table 2. The gneisses vary
in terms of their major element concentrations. The biotite-
hornblende gneiss has the lowest SiO2 (63.6 – 66.5 wt. %) content,
followed by the biotite gneiss (SiO2= 69.1 – 70.8 wt. %) with the
felsic augen gneiss having the highest SiO2 (76.2 wt. %) content.
However, the concentrations of the ferromagnesian elements are
highest in the biotite-hornblende gneiss (Fe2O3t= 4.65 – 5.44 wt.
%, and MgO = 1.79 – 2.07 wt. %), and lowest in the felsic augen
gneiss (Fe2O3t= 1.11 wt. %, and MgO = 0.12 wt. %). The biotite
gneiss, on the other hand, has intermediate content of the
ferromagnesian elements (Fe2O3t= 2.45 – 4.47 wt. %, and
MgO = 0.61 – 0.74 wt. %). The migmatites show lower concen-
trations of SiO2 (61.7 – 66.3 wt. %) than the gneisses; nonetheless,
they have higher contents of the ferromagnesian elements
(Fe2O3t= 4.07 – 6.70 wt. %, and MgO= 1.43 – 2.88 wt. %) than
the gneisses. The intrusive granitoids have SiO2 content of 64.7 –
74.0 wt. %, Fe2O3 of 1.49 – 3.65 wt. %, and MgO of 0.29 – 1.13 wt.
%. The pegmatite also has a SiO2 content of 71.9 wt. %, Fe2O3 of
0.99 wt. % and MgO of 0.22 wt. %. The migmatites and biotite-
hornblende gneiss have low K2O/Na2O values (K2O/Na2O= 0.2 –
0.7 and 0.1 – 0.5, respectively). The biotite gneiss, intrusive
granitoids, felsic augen gneiss and pegmatite have high K2O/Na2O
values (K2O/Na2O = 0.5 – 1.3, 0.7 – 1.4, 1.3, and 3.9), respectively.

All the samples plotted in the igneous field on the SiO2 vs. TiO2

diagram (Figure 7(a)). The intrusive granitoid, pegmatite and felsic
augen gneiss are slightly peraluminous. However, the biotite-
hornblende and biotite gneisses show both metaluminous and
weak peraluminous signatures (Figure 7(b)). Generally, the rocks
have typical I-type signatures (Figure 7(b)). The intrusive
granitoids, biotite gneiss, pegmatite and felsic augen gneiss are
classified as granite, except one sample each of the intrusive
granitoid and biotite gneiss that plot as quartz monzonite
(Figure 7(c)). The migmatites show variable compositions as they
plot as granodiorite, monzonites and on the boundary line between
monzonite and quartz-monzonite (Figure 7(c)). The biotite-
hornblende gneiss shows major element compositions akin to
granodiorite. On the feldspar normative diagram after O’Connor
(1965) (Figure 7(d)), the intrusive granitoids and biotite gneiss

dominantly plot as granite, with one sample each plotting as
trondjhemite. The pegmatite and felsic augen gneiss are classified
as granite, with the biotite-hornblende gneiss plotting entirely as
tonalite. The migmatites are classified as granodiorite and tonalite.
The felsic augen gneiss, biotite gneiss, migmatite and intrusive
granitoids are High-K calc-alkaline in nature (Figure 7(e)).
However, one sample of each of the biotite gneiss and migmatite
shows Medium-K calc-alkaline and Low-K tholeiite signature,
respectively. The biotite-hornblende gneiss has Low-K tholeiite
and Medium-K calc-alkaline signatures (Figure 7(e)). The
migmatite, biotite-hornblende gneiss and pegmatite are magne-
sian, whereas the intrusive granitoids and biotite gneiss are both
magnesian and ferroan (Figure 7(f)). The felsic augen gneiss plots
in the ferroan field (Figure 7(f)).

The granitoids of the internal nappes zone of the Dahomeyide
belt show a wide range of trace element concentrations. These wide
variations of trace element concentrations have resulted in distinct
REE patterns on the chondrite-normalized REE diagram by Palme
and O’Neill (2014). The biotite gneiss shows gentle negative slopes
with enrichment of the Light Rare Earth Elements (LREE) relative
to the Heavy Rare Earth Elements (HREE) and pronounced
negative Eu anomalies (Figure 8(a); La/Yb = 12.2 – 32.3; Eu/
Eu* = 0.4 – 0.5). The migmatites and biotite-hornblende gneiss
depict similar REE patterns characterized by LREE enrichment and
nearly flat HREE (Figures 8(b) and (c); La/Yb = 5.5 – 9.3 and 5.3 –
7.4, respectively). However, the migmatites show more noticeable
Eu anomalies than the biotite-hornblende gneiss (Figure 8(b); Eu/
Eu* = 0.6 and 0.7, respectively). Although the REE pattern for the
felsic augen gneiss resembles that of the migmatites, the HREEs are
slightly depleted in the felsic augen gneiss with pronounced Eu
anomalies compared to the migmatites (Figure 8(d); La/Yb = 9.2;
Eu/Eu* = 0.4). The intrusive granitoids show a steep negative slope
depicted by enrichment of the LREE and a significant depletion of
the HREE and pronounced negative Eu anomalies (Figure 8(e); La/
Yb= 40.9 – 47.4; Eu/Eu* = 0.3 – 0.6). Conversely, the pegmatite
shows LREE enrichment, HREE depletion and positive Eu
anomaly (Figure 8(f); La/Yb = 34.9; Eu/Eu* = 1.0). On the
incompatible multi-element normalized to primitive mantle
diagrams, the biotite gneiss is enriched in the LILE relative to
the HFS with negative peaks in Ba, Nb-Ta, Sr P and Ti
(Figure 9(a)). The patterns depicted by the migmatites and
biotite-hornblende gneiss are characterized by both LILE enrich-
ment and depletion and nearly flat HFS, with negative peaks in Nb-
Ta, P and Ti (Figures 9(b) and (c)). Their overall trace element
concentration is lower than the biotite gneiss. The felsic augen
gneiss shows an incompatible trace elements pattern comparable
to the biotite gneiss (Figure 9(d)) except for the positive peak in K.
The intrusive granitoids show enrichment of the LILE and a
significant depletion of the HFS and pronounced negative Nb-Ta,
P and Ti peaks (Figure 9(e)). The pegmatite, on the other hand,
shows LILE enrichment, HFS depletion, positive K and Sr peaks
and negative Nb-Ta, P and Ti peaks (Figure 9(f)).

7. Discussion

7.1. Significance of the deformational events to the
Pan-African orogeny

From a broader perspective, our detailed structural analysis
suggests that the internal nappes zone of the Dahomeyide belt,
southeastern Ghana, has been affected by a major NW-SE
shortening followed by NW-SE thrusting and a later extension

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Table 2. Major and trace element data of internal nappes zone of the Dahomeyide belt

Felsic Augen gneiss Biotite gneiss Migmatite

SAMPLE ENK03 EN09 ENAQ6 ENMTS01 ENK01 ENAQ8 ENAQ1 ENMTS02

wt. %

SiO2 76.2 70.8 70.6 70.8 69.1 61.7 62.9 66.3

TiO2 0.08 0.43 0.31 0.45 0.52 0.71 0.73 0.55

Al2O3 14.25 14.25 15.25 14.65 14.8 16.1 16.65 14

Fe2O3 1.11 2.99 2.45 3.05 4.47 6.59 6.7 4.07

MnO 0.04 0.05 0.05 0.05 0.06 0.1 0.1 0.14

MgO 0.12 0.61 0.74 0.66 0.66 2.85 2.88 1.43

CaO 1.3 1.84 2.69 2.05 2.24 2.74 2.82 6.12

Na2O 3.7 3.5 4.66 3.76 3.96 4.1 4.21 4.38

K2O 4.81 4.48 2.45 4.24 4.23 2.95 3.06 0.67

P2O5 0.02 0.11 0.15 0.12 0.14 0.17 0.18 0.13

LOI 0.3 0.26 0.6 0.4 0.62 0.69 0.67 0.33

Total 102 99.41 100.05 100.32 100.9 98.79 100.99 98.16

Mg# 18 29 37 30 23 46 46 41

ppm

Co 1 5 5 5 6 18 17 9

Ni 2 4 6 4 4 33 32 14

Cr 10 10 20 10 10 60 60 30

V 5 23 35 23 25 123 125 86

Sc 2 7 4 6 7 17 17 11

Ga 19 20.3 21.6 20.5 25.3 17.8 18.7 14.7

Pb 20 19 16 21 14 11 9 11

Cs 0.72 6.91 3.05 6.55 1.72 14 13 1.45

Rb 105.5 196 111 186.5 115.5 179 182 42.2

Ba 459 627 642 624 771 453 451 94.9

Th 11.5 25.6 16.05 21.7 17.15 5.27 5.5 4.8

U 2.2 7.1 2.97 2.78 1.56 1.81 2.02 3.25

Nb 11.4 25.6 15 28.6 36.8 8.6 9.7 10.7

Ta 0.2 2.5 1 2.8 1.9 0.5 0.6 1.7

La 15.5 71.2 41.1 52.2 66 23.8 23.5 19.2

Ce 30 142.5 86.1 105 133.5 46.8 46 38.2

Pr 3.44 15.65 9.46 11.8 15.2 5.61 5.55 4.7

Sr 156 168 271 181 190 298 293 280

Nd 12.7 56.7 35.5 43.3 57.8 22.8 21.8 19.3

Sm 3.18 9.82 6.49 8.64 11.8 4.98 4.57 4.46

Zr 84 265 253 276 372 157 172 145

Hf 3.6 7.8 6.7 7.9 10.2 4.3 4.7 4

Eu 0.65 0.94 0.96 0.9 1.17 1.01 1.11 1.06

Gd 2.7 7.48 4.32 6.89 10.6 4.2 3.97 4.26

Tb 0.42 1.06 0.57 1.03 1.67 0.63 0.64 0.7

Dy 2.45 5.76 2.82 5.8 9.62 3.78 3.66 4

Y 13.6 28.7 13.4 28.8 49.1 19.6 18.3 24

(Continued)

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Table 2. (Continued )

Felsic Augen gneiss Biotite gneiss Migmatite

SAMPLE ENK03 EN09 ENAQ6 ENMTS01 ENK01 ENAQ8 ENAQ1 ENMTS02

Ho 0.47 0.99 0.52 1.04 1.93 0.78 0.73 0.83

Er 1.39 2.72 1.16 2.84 5.23 2.24 2.03 2.38

Tm 0.21 0.36 0.15 0.39 0.68 0.34 0.28 0.34

Yb 1.18 2.33 0.89 2.24 3.79 2.22 1.76 2.46

Lu 0.17 0.32 0.13 0.36 0.57 0.31 0.28 0.36

Hornblende-biotite gneiss Pegmatite Intrusive granitoids

SAMPLE ENAQ3 ENAQ9 ENAQ90 ENAQ02 ENK02 EN12 ENKP03 EN13 ENAQ4

wt. %

SiO2 66.5 63.6 64.5 71.9 64.7 74 74 72.2 70.9

TiO2 0.64 0.64 0.59 0.12 0.75 0.18 0.19 0.21 0.37

Al2O3 14.8 13.4 13.75 14.7 15.95 14.15 14.55 14.33 14.88

Fe2O3 5.11 5.44 4.65 0.99 3.65 1.51 1.49 3.33 2.22

MnO 0.11 0.2 0.18 0.01 0.03 0.03 0.03 0.03 0.03

MgO 2.07 1.79 1.67 0.22 1.13 0.29 0.33 0.44 0.58

CaO 3.1 9.5 8.34 0.66 2.67 1.46 1.59 1.86 1.91

Na2O 3.95 4.04 4.28 2.17 4.73 3.68 3.75 3.08 4.05

K2O 2.16 0.3 0.31 8.55 3.31 4.41 4.6 4.16 4.11

P2O5 0.16 0.18 0.14 0.02 0.25 0.05 0.06 0.18 0.12

LOI 0.66 0.35 0.31 0.43 1.01 0.24 0.67 0.96 0.64

Total 99.39 99.5 98.78 100.06 98.39 100.1 101.39 100.80 99.96

Mg# 45 39 42 31 38 28 30 21 34

ppm

Co 12 12 10 2 8 2 1 6 4

Ni 15 19 16 2 5 2 2 5 3

Cr 40 50 90 10 10 10 10 15 10

V 117 122 107 6 75 7 10 46 31

Sc 14 13 11 1 3 2 2 4 2

Ga 14.8 14.5 14.7 12.8 20.9 18.7 17.6 28.60 19.07

Pb 9 12 14 36 10 25 31 33 22

Cs 6.49 0.13 0.1 3.22 1.27 5.77 2.85 4.95 3.30

Rb 100.5 3.9 3.6 232 107 186.5 162 228 152

Ba 633 76.6 73.7 2330 1365 720 880 1483 988

Th 3.07 3.75 3.89 4.27 10.05 21.4 11.55 21.5 14.33

U 1.02 2.09 2.68 2.35 0.63 1.86 1.53 2.01 1.34

Nb 6.3 6.3 7.9 4 10.2 14.2 9.6 17.0 11.3

Ta 0.7 0.5 0.9 0.5 0.7 0.7 0.5 1.0 0.6

La 15.8 19.6 19 14 75.9 36.2 23.4 67.8 45.2

Ce 33.5 37 39.2 21.8 148.5 69.8 42.9 130.6 87.1

Pr 4.27 4.31 4.8 2.19 15.95 7.49 4.55 14.00 9.33

Sr 443 345 352 330 527 182.5 274 492 328

Nd 18.1 17.7 19.6 7.8 56.7 26.7 16.5 50.0 33.3

Sm 3.69 3.62 4.23 1.42 8.37 5.07 3.11 8.28 5.52

(Continued)

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event (orogenic collapse). These shortening, thrusting and
extension events are expressed as four deformation phases (D1-
D4), which occurred during various stages of the Pan-African
orogeny. The D1 phase is widespread and represents NW-SE
Pan-African shortening associated with the regional phase of
crustal movement that resulted in westward nappe piling during
the Pan-African continent-continent collision between the West
African Craton (WAC) and BNS. Attoh et al. (2007) and Kwayisi
et al. (2020) have suggested that the transition from continental
subduction to continent-continent collision resulted in a change in
orogenic structural grain from N-S to NE-SW fabric. Rotation of
regional E-W shortening direction to NW-SE shortening direction
produced theNE-SW fabrics between 600 and 580Ma. The presence
of asymmetric quartz porphyroblasts indicates a shearing compo-
nent with a general dextral top-to-the-NE sense of movement
during the D1 event.

The D2 deformational regime followed the D1 shortening shear
deformation, representing a Pan-African thrusting event as a result
of progressive NW-SE shortening. Thrusting resulted in the
transposition of the D1 fabrics. The D2 deformation is a ductile
shear deformation that formed S2 foliations (cleavages), F2 folds,
kink folds and coeval with C2 shear faults. The main kinematic
indicators associated with the D2 event are the near horizontal
NW-dipping L2 stretching lineation and small-scale C2 shear faults
with a top-to-the-NW dextral sense of movement observed in the
field and processed aeromagnetic data (Figures 5(c), (d) and 6(d)).
D2 corresponds probably with west-verging thrusting and
exhumation of the HP rocks between 590 and 580 Ma (Attoh
et al. 1997; Affaton et al. 2000). The main S1 foliations are
observable in microscopic and mesoscopic scales and are much
more spectacular than the younger S2 foliations. This means the
D1 event was rather intense, with better-preserved structures
than the D2 event. This interpretation is backed by shallow
inter-limb angle and parallel limbed isoclinal folds associated
with the D1 tectonic phase.

The D3 event corresponds to a shear deformational regime in
which the sinistral shear faults were produced. The D4 brittle
tectonic event marked the last deformational and geological
event in the evolutionary sequence of the internal nappes zone
of the Dahomeyide belt. The significance of the D3 and D4

deformational events is unclear; however, D3 could be a
continuation of the thrusting phase of the Pan-African orogeny
since it shares similar structural grains as D2, whereas D4 may be
linked to the extensional-related volcanic and sedimentary
rocks formed after Pan-African continent-continent collision
(Ganade de Araujo et al. 2016).

7.2. Tectonic setting

Petrographical investigation revealed that the rocks had undergone
veryminimal alteration and that, coupled with the very low Loss on
Ignition (LOI) values (<1.05 wt. %), suggests insignificant
elemental mobility; thus, the major and trace element composi-
tions can be utilized in tectonic setting and petrogenetic
interpretations. The internal nappes zone has been proposed to
be a juvenile arc crust with pockets of reworked Paleoproterozoic
rocks intruded by post-collisional granitoids, representing the
active margin of the Dahomeyide belt (Kalsbeek et al. 2012; Attoh
et al. 2013). Field, petrographical and structural data reveal two
main rock categories. These are (i) deformed rocks made up of
gneisses and migmatites and (ii) undeformed rocks comprising
mainly intrusive granitoids of granite and granodiorite composi-
tion (Figures 2, 3, and 4). Several tectonic discrimination diagrams,
coupled with trace element patterns and ratios, have been used to
assess the tectonic setting of the formation of these granitoids. The
overall trace element patterns of the studied granitoids are
characterized by enrichment of LILE and depleted HFS, with
negative peaks of Nb-Ta, Sr, P and Ti (Figure 9). These
geochemical features are typically considered as indications of
subduction processes (Spandler and Pirard, 2013; Kelemen et al.
2014). Except for three samples of biotite gneiss that plot in the
within-plate granitoid field, all the other samples plot in the field
defined by volcanic-arc and syn-collisional granitoids (Figure 10(a)).
The Zr verses (Nb/Zr)N diagram by Thiéblemont and Tégyey (1994)
suggests the pegmatite, felsic augen gneiss, biotite gneiss and
majority of the intrusive granitoids show geochemical signatures
typical of granitoids derived from continent-continent collision, i.e.
active margin environment (Figure 10(b)). The biotite-hornblende
gneiss, migmatites and two samples of biotite gneiss plot within the
arc-array and the field defined by continental arc (Figure 10(c)).

Table 2. (Continued )

Hornblende-biotite gneiss Pegmatite Intrusive granitoids

SAMPLE ENAQ3 ENAQ9 ENAQ90 ENAQ02 ENK02 EN12 ENKP03 EN13 ENAQ4

Zr 126 148 147 31 377 132 107 308.00 205.33

Hf 3.5 3.9 4.1 1 8 4.3 3.4 7.9 5.2

Eu 1.09 1.12 1.24 0.96 1.51 0.55 0.58 1.32 0.88

Gd 3.63 3.69 4.04 0.97 4.89 3.7 2.37 5.48 3.65

Tb 0.55 0.56 0.6 0.1 0.58 0.47 0.31 0.68 0.45

Dy 3.44 3.24 3.72 0.46 2.75 2.17 1.25 3.09 2.06

Y 20.6 19.4 23.1 2.5 13.5 10.2 5.8 14.75 9.83

Ho 0.75 0.66 0.79 0.08 0.47 0.36 0.21 0.52 0.35

Er 2.28 2.16 2.47 0.2 1.26 0.78 0.53 1.29 0.86

Tm 0.35 0.31 0.36 0.04 0.18 0.11 0.05 0.17 0.11

Yb 2.26 1.85 2.49 0.28 1.12 0.55 0.4 1.04 0.69

Lu 0.32 0.31 0.4 0.04 0.13 0.09 0.04 0.13 0.09

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Although the felsic angen gneiss, pegmatite, biotite gneiss and
intrusive granitoids plot in the continental arc field, they plot slightly
away from the arc-array field (Figure 10(c)). This geochemical
feature may suggest significant crustal contamination of the
intrusive granitoids and pegmatite, and to some extent, the biotite
and felsic augen gneisses.

R1 (4Si-11(NaþK)-2(FeþTi)) verse R2 (6Caþ2MgþAl) tec-
tonic discriminating diagram (after Batchelor and Bowden, 1985)
(Figure 10(d)) puts the rocks of the internal nappes zone into
various orogenic phases consistent with field and petrographical
evidence. On this diagram, the biotite-hornblende gneiss shows
pre-collisional signatures. At the same time, the migmatites

Figure 7. (Colour online) Major element classification diagrams of the gneisses, migmatite and intrusive granitoids of the internal nappes zone (a) Plot of SiO2 vs. TiO2 (Tarney
1977), (b) Plot of A/CNK (molar Al2O3/(CaOþ Na2Oþ K2O)) vs. ANK (molar Al2O3/(Na2Oþ K2O)) (Maniar and Piccoli 1989), (c) Total alkalis vs silica (Middlemost 1985), (d) Or-Ab-An
ternary diagram (O’Connor, 1965), (e) K2O vs. SiO2 diagram (after Peccerillo and Taylor 1976) and (f) SiO2 vs. FeOt/(FeOtþMgO) diagram (after Frost and Frost 2008).

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straddle between pre and syn-collisional settings, with the biotite
and felsic augen gneisses showing syn-collisional features. The
intrusive granitoids plot in the late orogenic field, with the
pegmatite plotting between syn-collision and an orogenic granite
boundary (Figure 10(d)). Typical collisional features such as
foliations and folds, which occur in most of the gneisses and
migmatites, represent the compressive stages of orogenesis. The
deformed rocks (gneisses and migmatites) of the internal

nappes zone with dominant axial planar foliations indicate their
formation in a collisional setting or were affected by the Pan-
African collisional process. The continental-arc signatures
imply continental subduction processes in their formation.
The intrusive granitoids and pegmatite are undeformed,
implying late- to post-orogenic emplacement; thus, the
continental-arc features could result from contamination
during their evolution.

Figure 8. (Colour online) Chondrite-normalized REE diagrams of (a) biotite gneiss, (b) Migmatites, (c) biotite-hornblende gneiss, (d) felsic augen gneiss, (e) intrusive granitoids
and (f) pegmatite. Chondrite and primitive normalizing values are from Palme and O’Neill, (2014).

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7.3. Petrogenesis

7.3.1. Lithological evolution
Petrographical and geochemical studies indicate that the rocks of
the internal nappes zone are gneisses, migmatite and intrusive
granitoids of granite, granodiorite and tonalite with minor
trondjhemite compositions, formed during and after the
Pan-African subduction-collision events. The gneisses and
migmatites are pre- to syn-collisional granitoids, whereas the
intrusive granitoids are post-collisional. Results of this study show

that the migmatites are the most abundant rock in the Pan-African
Dahomeyide internal nappes zone in southeastern Ghana,
suggesting widespread migmatization during the Pan-African
orogeny. The migmatites consist of biotite-rich gneissic melano-
somes and feldspar-rich granitic leucosomes, resulting in
lithological heterogeneity. Johnson et al. (2013) suggested that
granitic leucosomes with abundant K-feldspar represent areas
dominated by segregated crystal melt. Sawyer (1999) also described
melanosomes as evident sites of melt formation, while leucosomes

Figure 9. (Colour online) Primitive mantle-normalized diagrams of (a) biotite gneiss, (b) Migmatites, (c) biotite-hornblende gneiss, (d) felsic augen gneiss, (e) intrusive granitoids
and (f) pegmatite. Chondrite and primitive normalizing values are from Palme and O’Neill (2014).

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are sites of melt collection. From field and petrographical data,
these features are characteristics of the migmatites of the
Dahomeyide internal nappes zone, which suggests the migmatites
resulted from partial melting of pre-existing rocks (gneisses)
following Kornprobst (2002). Consequently, the lithological
heterogeneity observed in the migmatites may be due to partial
melting of the gneisses. Geochemical classification diagrams
indicate that the migmatites and biotite-hornblende gneiss evolved
from similar granodioritic-tonalitic protolith (Figures 7(c) and
(d)). Thus, the migmatites might have evolved from the biotite-
hornblende gneiss through crustal anataxis during amphibolite
facies metamorphism (Table 1), as described by Nude (1995).

Field relations, including cross-cutting relationships, grada-
tional and sharp lithological contact, and inclusions, among others,
have been used to establish the relative formation period of the
gneisses, migmatite and intrusive granitoids of the internal nappes
zone. The leucosomes slightly cut across the melanosomes in the
migmatites, implying that the former is relatively younger than the
latter. Textural evidence shows that the melanosome is rich in
biotite but more depleted in feldspars and quartz than the
leucosome. The felsic augen gneiss may have formed due to the
gradual mineral growth associated with metamorphism and
shearing. Gradational boundaries between the migmatites and
gneisses imply a gradual transition from gneiss to migmatite with

increasing temperature and the onset of partial melting. Pockets of
gneisses occur within the intrusive granitoids, and this, coupled
with the sharp contacts between the intrusive granitoids and
gneisses (Figures 4(a) and (b)), indicate an intrusive relationship
between the two. Besides, the gneisses are significantly deformed,
whereas the intrusive granitoids are undeformed. The intrusive
granitoids, biotite gneiss and felsic augen gneiss share similar
lithological compositions, i.e., granite and granodiorite (Figure 7(c)
and (d)). Thismay be amanifestation of the derivation of the intrusive
granitoids from the partial melting of the biotite and felsic augen
gneisses. This could explain the similar REE, LILE and HFS patterns
depicted by the intrusive granitoids and the biotite gneiss on the REE
and multi-element diagrams (Figures 8 and 9). In addition, these
rocks show similar tectonic setting characteristics (Figure 11). The
cross-cutting relationship between the pegmatite veins and migma-
titic layers indicates a relatively younger age of the pegmatite than the
migmatites.

7.3.2. Magma source and depth of emplacement
Major and trace elements geochemical data in Table 2 show low
Mg (Mg# = 14.77-44.5), very low Ni (1-19ppm) and Cr (10-
50ppm) contents for the gneisses, migmatite and intrusive
granitoids. These features suggest the formation of the gneisses,
migmatite and intrusive granitoids from evolved magmas rather

Figure 10. (Colour online) Tectonic discriminant diagrams for the rocks of the internal nappes zone of the Dahomeyide belt (a) Nb vs. Y after Pearce et al. (1984),
(b) Zr vs. (Nb/Zr)N diagram of Thiéblemont and Tégyey (1994), (c) Th/Yb vs. Nb/Yb with reference fields modified after Pearce (2008) and (d) R1-R2 (after Batchelor and
Bowden, 1985).

Crustal growth and evolution of the Dahomeyide belt 15

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than primary magmas whose Mg# >65, Cr >1000 ppm, and Ni
>400-500 ppm (Winter, 2001). The rocks of the internal nappes
zone of the Dahomeyide belt, southeastern Ghana, are generally
I-type granitoids with metaluminous and weak peraluminous
features (Figure 7(b)). The intrusive granitoids, biotite and felsic
gneisses and some of the migmatite are High-K calc-alkaline in
nature. Partial melting of crustal rocks, or subduction-influenced
mantle, has been proposed to generate High-K calc-alkaline
granitoids (Gläser et al. 2022). The High-K calc-alkaline signature
and their I-type nature may suggest the melting of older igneous
crustal materials. Besides, the intrusive granitoids show similar
lithological compositions and trace element characteristics as the
biotite gneiss, indicating partial melting of the latter to form the
former. The Low-K tholeiite, metaluminous and I-type signatures
of the biotite-hornblende gneiss and one sample of the migmatites
suggest the melting of intermediate to mafic rocks. All the rocks of
the internal nappes zone have Mg# values akin to granitoids
derived from the lower crust (Figure 11).

The gneisses, migmatite and intrusive granitoids show LREE
enrichment relative to HREE with a pronounced Eu negative
(Eu/Eu*) anomaly, except for the pegmatite, which has a positive
Eu anomaly. The REE pattern, together with the negative Ba, Sr
and Eu anomalies, might be associated with residual plagioclase at
the source or formation of their magmas in an oxidized
environment, such as the continental crust (Rudnick and Gao,
2014). The continental crust is typically enriched in LREE and
LILE but strongly depleted in Ti, Nb and Ta (Rollinson (1993), as is
the case of the gneisses, migmatite and intrusive granitoids of the
internal nappes zone (Figures 8 and 9). The depletion in Ti, Nb and
Ta, evident on the primitive mantle normalized multi-element plot
(Figure 9), together with weak positive Zr-Hf anomalies exhibited
by the rocks, are diagnostic characteristics of the continental crust,
while the depletion in Ba suggests an active margin source (Elburg,
2010; Rudnick and Gao, 2014). Negative Nb-Ta and Ti anomalies
suggest relative enrichment of other elements by fluids or melt
from a subducting plate in an arc setting (Elburg, 2010). The low
Sr/Y ratios, with corresponding high Yb>1.5 ppm and Y>10 ppm
content for the rocks of the internal nappes zone, support the
melting of crustal material in their formation. On the SiO2 verse Mg#
(Figure 11), the migmatites and biotite-hornblende gneiss plot in the

region of delaminated lower crust-derived granitoids, whereas the
biotite and felsic augen gneisses, intrusive granitoids and pegmatite
plot in the field of thick lower crust-derived granitoids. This suggests
themelting of a delaminated and/or thickened lower crust to form the
gneisses, migmatite and intrusive granitoids.

Field studies have revealed that the gneisses and migmatites are
deformed, with deformation features defined by foliations, folds,
thrust and shear zone. These deformational features have been
attributed to major shortening, shearing and thrusting events
during the Pan-African orogeny. Such structures provide a
historical record of deep (middle to lower) crustal level
emplacement and deformation of the rocks (Opare-Addo et al.
1993). Thus, it is likely that the depth of emplacement of these
rocks is ≤ 35 km (lower crust) (Hacker et al. 2015; Aidoo et al.
2020; Aidoo et al. 2021). This is confirmed by the SiO2 verse Mg#
diagram (Figure 11), where the granitoids show geochemical
characteristics of delaminated and/or thick lower crust.

7.4. Implications for crustal growth and evolution of the
Dahomeyide belt active margin

Petrographical investigation and geochemical signatures suggest
that the gneisses, migmatite and intrusive granitoids of the internal
nappes zone, which represents the active margin of the Dahomeyide
belt, are I-type, metaluminous and weakly peraluminous granitoids
of tonalite, granodiorite and granite signatures formed during
pre-, syn- and post-collisional orogenic setting. In this study, the
biotite-hornblende gneiss formed during the pre-orogenic phase of
the Pan-African orogeny in an arc setting. This gneiss may
correspond to the basement of the Benin-Nigerian shield (Duclaux
et al. 2006; Attoh et al. 2013). Older U-Pb zircon crystallization ages
ranging from 2.14 to 2.19 Ga recorded for the hornblende gneiss
have been interpreted to suggest the involvement of older
Paleoproterozoic crust (Saharan Metacraton), representing the
basement of the Benin-Nigerian Shield, in the Pan-African
Dahomeyide belt (Duclaux et al. 2006; Attoh et al. 2013). The
biotite-hornblende gneiss in this study shows tonalite and
granodiorite composition. Hence, the Paleoproterozoic basement
of the Benin-Nigerian Shield evolved from I-type, metal-
uminous, tonalitic-granodioritic magma emplaced in a
continental-arc setting. This was later deformed and remobilized
(migmatized) during the Pan-African orogeny.

Tectonic discriminations suggest continental arc and con-
tinent-continent collision for the migmatites and biotite gneiss,
respectively (Figure 10). Plate convergence (both ocean and
continental subduction) and arc magmatism formed approxi-
mately 670 to 630 Ma, followed by continent-continent collision of
the WAC with the BNS between 620 and 610 Ma, which is
characterized by HP metamorphism have been proposed as the
geodynamic evolution of the Dahomeyide belt (Attoh, 1998;
Agbossoumondé et al. 2001; Duclaux et al. 2006; Attoh and Nude,
2008; Ganade de Araujo et al. 2016). A double subduction system
(island arc and active continental margin) occurred in the north
(Benin and northern Togo), which evolved into a single subduction
system (continental subduction) in the south (Ghana; Guillot et al.
2019). This was followed by a continent-continent collision between
theWAC and the Benin-Nigerian Shield (Kwayisi et al. 2020). Thus,
themigmatitesmight have formedduring the continental subduction
phase of the Pan-African orogeny and later metamorphosed and
deformed during the continent-continent collision between the
WAC and BNS. This occurred due to the partial melting of the
continental crust (i.e. the biotite-hornblende gneiss) of tonalite and

Figure 11. (Colour online) SiO2 vs. Mg# plot for the rocks of the internal nappes zone
of the Dahomeyide belt for petrogenetic interpretation. Fields of mantle, subducted
oceanic crust, pure oceanic crust, delaminated lower crust, thick lower crust and
metabasalt and eclogite melts are from Wang et al. (2006).

16 D Kwayisi et al.

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granodiorite affinity at a depth of ≤35 km (Figure 11). This implies
that large-scale migmatization occurred during the convergence
process of the Pan-African orogeny through crustal anatexis.

Geochemical features of the intrusive granitoids and some of
the biotite gneiss indicate High-K calc-alkaline granitoids formed
by partially melting the thick lower crust in a post-collisional
setting. According to Liégeois et al. (1998), a post-collisional
environment characterized by substantial motions along shear
zones could have resulted in the re-melting of an earlier continental
crust due to subduction in the lithospheric mantle or lower crust.
Furthermore, Lu et al. (2015) and Eglinger et al. (2017) revealed
that High-K calc-alkaline and shoshonitic granitoids are frequently
placed in arc and post-collisional settings, preceded by a crustal
thickening phase. The Dahomeyide belt post-collisional magma-
tism occurred between 580 and 540Ma (Kalsbeek et al. 2012; Attoh
et al. 2013; Ganade de Araujo et al. 2016; Guillot et al. 2019). Thus,
the active margin of the Dahomeyide belt evolved during the
subduction-collisional and post-collisional phases of the Pan-
African orogeny between the Cryogenian and Ediacaran periods
(670 – 540 Ma). This evolution witnessed large-scale migmatisa-
tion, crustal thickening and granitoid intrusions through partial
melting of the thickened continental crust. The growth of the active
margin occurred through tonalite-granodiorite magmatism due to
the partial melting of the delaminated lower crust. This was
followed by large-scale migmatization due to the remobilization of
pre-existing crustal rocks during continental subduction. Then,
crustal thickening due to continent-continent collision followed by
melting of the thickened crust to form the intrusive granitoids
(granite and granodiorite).

8. Conclusion

Integrated field, petrographical, geophysical, structural and
geochemical studies of granitoids from the internal nappes zone
(i.e., active margin) of the Dahomeyide belt are presented in this
research. Two main lithological units, (i) deformed meta-granitoids
made up ofmigmatites and gneisses and (ii) undeformed granitoids,
including granite and granodiorite, dominate the internal nappes
zone of southeastern Ghana. These granitoids have been affected by
four deformation phases (D1-D4) during amajorNW-SE shortening
followed by NW-SE dextral-sinistral thrusting and a later exten-
sional event during the Pan-African orogeny. Petrographical and
geochemical studies indicate that the gneisses, migmatite and
intrusive granitoids of the internal nappes zone are of granite,
granodiorite and tonalite composition, formed during and after the
Pan-African subduction-collision events. The gneisses and migma-
tite with dominant foliations and folds indicate their formation in a
collisional setting or were affected by the Pan-African collisional
process because these features are associated with compressive
processes. The continental-arc signatures of the gneisses and
migmatites imply continental subduction processes in the formation
of their protolith. The intrusive granitoids are undeformed, implying
late- to post-orogenic emplacement; thus, the continental-arc
features could result from contamination during their evolution.
The active margin of the Dahomeyide belt evolved during the
subduction-collisional and post-collisional phases of the Pan-
African orogeny. This evolution witnessed large-scale migmatiza-
tion and granitoid intrusions through partial melting of thickened
continent crust.

Acknowledgement. The authors thank the Department of Earth Science
Capacity Building Project for supporting this research financially.

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https://doi.org/10.1017/S0016756823000808

	Cryogenian-Ediacaran crustal growth and evolution of the active margin of the Dahomeyide belt, Ghana
	1. Introduction
	2. Geological setting
	3. Field relations and petrography
	4. Structures and deformation
	5. Geophysical data processing and interpretation
	5.1. Geophysical data processing
	5.2. Geophysical data interpretation

	6. Geochemical characteristics
	6.1. Analytical procedure
	6.2. Major and trace element concentrations

	7. Discussion
	7.1. Significance of the deformational events to the Pan-African orogeny
	7.2. Tectonic setting
	7.3. Petrogenesis
	7.3.1. Lithological evolution
	7.3.2. Magma source and depth of emplacement

	7.4. Implications for crustal growth and evolution of the Dahomeyide belt active margin

	8. Conclusion
	References