Deformation mechanisms, mineral chemistry and zircon U-Pb geochronological constraints in the south Patos shear zone: implications for the crustal evolution of the Borborema Province, NE Brazil

Souza, Carolina Peixoto de; Viegas, Luis Gustavo Ferreira; Santos, Lauro Cézar Montefalco de Lira

doi:10.1590/2317-4889202120210048

Carolina Peixoto de Souza

Instituto de Geociências, Universidade de Brasília – Brasília (DF), Brazil. E-mails: carolinapdesouza@gmail.com, lgviegas@unb.br

https://orcid.org/0000-0001-7186-2693

Luis Gustavo Ferreira Viegas ^**Corresponding author.

Instituto de Geociências, Universidade de Brasília – Brasília (DF), Brazil. E-mails: carolinapdesouza@gmail.com, lgviegas@unb.br

https://orcid.org/0000-0002-9945-6256

Lauro Cézar Montefalco de Lira Santos

Departamento de Geologia, Universidade Federal de Pernambuco – Recife (PE), Brazil. E-mail: lauro.lsantos@ufpe.br

https://orcid.org/0000-0001-6098-1873

*Corresponding author.

C.S. conducted fieldwork, performed petrographic and microstructural analyses, developed analytical work on the collected samples, treated the obtained geochronological data and wrote the original draft of the manuscript. L.V. conducted fieldwork, supervised the microstructural and mineral chemistry analyses, reviewed/edited the original draft of the manuscript and acquired funding for the development of this research. L.S.treated the obtained geochronological data and reviewed/edited the original draft of the manuscript.

Competing interests: The authors declare no competing interests.

Figures (11)
Tables (3)

Thumbnail

Figure 1.
(A) Pre-drift reconstruction of South America-Africa exhibiting the Amazonian (AC), São Francisco (SFC), West African (WAC), and Congo (CC) Cratons, Brasiliano-Pan-African belts, and Andean Belt. The black square represents the Borborema Province; (B) Schematic map displaying the tectonic domains of the Borborema Province (northern, central, and southern) and the main shear zones: SSZ (Sobral Shear Zone); SPSZ (Senador Pompeu Shear Zone); PSZ (Patos Shear Zone); WPeSZ (West Pernambuco Shear Zone), and EPeSZ (East Pernambuco Shear Zone). The red square represents the study area; (C) Schematic geological map of the southern PSZ, displaying the Paleoproterozoic gneisses, migmatites and amphibolites of the basement, supracrustal rocks and Neoproterozoic granites and granodiorites (CAT-Catingueira pluton, ST-Santa Terezinha pluton). The locations of field mapping points (yellow dots), geochronological (blue dot), and EBSD samples (red stars) are shown. Regional units and lithological contacts compiled and modified from Brito Neves et al. (2003Brito Neves B.B., Passarelli C.R., Basei M.A.S., Santos E.J. 2003. Idades U-Pb em zircão de alguns granitos clássicos da Província Borborema. Geologia USP. Série Científica, 3:25-38. https://doi.org/10.5327/S1519-874X2003000100003
https://doi.org/https://doi.org/10.5327/... ), Archanjo et al. (2008Archanjo C.J., Hollanda M.H.B.M., Rodrigues S.W.O., Brito Neves B.B., Armstrong R. 2008. Fabrics of pre- and syntectonic granite plutons and chronology of shearzones in the Eastern Borborema, NE Brazil. Journal of Structural Geology, 30(3):310-326. https://doi.org/10.1016/j.jsg.2007.11.011
https://doi.org/https://doi.org/10.1016/... ), Hollanda et al. (2010Hollanda M.H.B.M., Archanjo C.J., Souza L.C., Armstrong R., Vasconcelos P.M. 2010. Cambrian mafic to felsic magmatism and its connections with transcurrent shear zones of the Borborema Province (NE Brazil): Implications for the late assembly of the West Gondwana. Precambrian Research, 178(1-4):1-14. https://doi.org/10.1016/j.precamres.2009.12.004
https://doi.org/https://doi.org/10.1016/... ), and Archanjo et al. (2021Archanjo C.J., Hollanda M.H.B.M., Viegas L.G.F. 2021. Late Ediacaran lateral-escape tectonics as recorded by the Patos shear zone (Borborema Province, NE Brazil). Brazilian Journal of Geology, 51(2):e20200132. https://doi.org/10.1590/2317-4889202120200132
https://doi.org/https://doi.org/10.1590/... ).

Thumbnail

Figure 2.
Field aspects of the basement rocks and metasedimentary sequences from the southern boundary of the Patos shear zone. (A) Banded gneiss showing fine to coarse-grained mafic and felsic bands, both parallel to the E-W mylonitic foliation of the Patos shear zone. (B) Contact between the mafic and felsic bands. The mafic band shows millimetric biotite crystals aligned to the mylonitic foliation, in addition to elliptical quartz grains and elongated feldspars. The felsic band presents centimeter-scale porphyroclasts of K-feldspar that are elongated and fractured. A quartz band parallel to the mylonitic foliation is observed close to the K-feldspar porphyroclast. (C) Medium- to coarse-grained metasedimentary rock with elonganted and stretched feldspar porphyroclasts immersed in a fine-grained, dark matrix; (D) Muscovite-rich, fine-grained metasedimentary rock with ultramylonitic texture. The mylonitic foliation is marked by elongated muscovite and biotite that are aligned with subordinate, stretched K-feldspar porphyroclasts.

Thumbnail

Figure 3.
Field aspects of the Santa Terezinha and Catingueira plutons. The coin used for scale is 23mm in diameter.: (A and B) Santa Terezinha granite showing a porphyroclastic texture marked by elongated K-feldspar porphyroclasts wrapped in quartz aggregates forming ribbons. Biotite crystals parallel to quartz grains evidence the mylonitic foliation. K-feldspar porphyroclasts can develop augen morphologies; (C and D) Catingueira pluton showing a light grey color, fine-grained equigranular texture, and an incipient foliation that is evidenced by the preferred orientation of millimetric biotite crystals.

Thumbnail

Figure 4.
Microstructures in the banded gneisses of the southern Patos shear zone (Qz: quartz, Kfs: K-feldspar, Pl: plagioclase, Bt: biotite, Whitney and Evans 2010Whitney D.L., Evans B.W. 2010. Abbreviations for names of rock-forming minerals. American Mineralogist, 95(1):185-187. https://doi.org/10.2138/am.2010.3371
https://doi.org/https://doi.org/10.2138/... ; Mtx: matrix) (A and B) Overview of typical mylonitic granite with porphyroclasts of K-feldspar and plagioclase wrapped in quartz ribbons and fine-grained recrystallized K-feldspar, plagioclase, quartz and biotite. The mylonitic foliation is defined by the preferred orientation of quartz ribbons, elongated feldspar clasts, and oriented biotite; (C and D) Sub-elliptical K-feldspar and plagioclase porphyroclasts embedded in the fine-grained recrystallized matrix and showing undulose extinction. A sinistral shear sense defined by asymmetric displacement along oblique microfractures is locally observed in plagioclase clasts [C]; Recrystallized grains rimming K-feldspar clast (red arrows) are strain-free and have lobate boundaries [D].

Thumbnail

Figure 5.
Microstructures of the Santa Teresinha pluton (Pl: plagioclase; Kfs: K-feldspar; Qz: quartz; Whitney and Evans 2010Whitney D.L., Evans B.W. 2010. Abbreviations for names of rock-forming minerals. American Mineralogist, 95(1):185-187. https://doi.org/10.2138/am.2010.3371
https://doi.org/https://doi.org/10.2138/... ). (A) Foliation-parallel quartz ribbons with undulose extinction and straight boundaries that define triple junctions (red arrows). Yellow arrows indicate subgrains; (B) Microfracture sets crosscutting plagioclase porphyroclasts; quartz ribbons (upper right) are in discrete contact with the clasts; (C and D) Sub-elliptical K-feldspar porphyroclasts displaying microfractures filled by the fine-grained matrix and surrounded by quartz ribbons.

Thumbnail

Figure 6.
Microstructures of the Catingueira pluton (Qz: quartz; Pl: plagioclase; Kfs: K-feldspar; Amp: amphibole; Bt: biotite; Whitney and Evans 2010Whitney D.L., Evans B.W. 2010. Abbreviations for names of rock-forming minerals. American Mineralogist, 95(1):185-187. https://doi.org/10.2138/am.2010.3371
https://doi.org/https://doi.org/10.2138/... ; Mtx: fine-grained matrix). (A) Plagioclase porphyroclast exhibiting a microfracture filled with quartz grains (red arrows) and weak deformation twins. (B) K-feldspar clast with undulose extinction wrapped in coarse-grained polycrystalline quartz aggregates and amphibole crystals that are partially altered to biotite (red arrows); (C) Quartz aggregates wrapping around plagioclase porphyroclasts. Subgrain boundaries in quartz grains are indicated by red arrows. (D) Quartz aggregate displaying straight boundaries and polygonal shapes that define triple junctions. Subgrain boundaries are indicated by red arrows. Amphibole occurs as grains parallel to the aggregate elongation.

Thumbnail

Figure 7.
Crystallographic fabrics of quartz grains in the host banded gneisses. See text for discussion.

Thumbnail

Figure 8.
Misorientation axes for low-angle (2-15º) and transitional, low- to high angle (10-45º) boundaries, as well as misorientation angle distributions for the banded gneisses. See text for discussion.

Thumbnail

Figure 9.
Chemical composition of porphyroclasts and recrystallized grains of K-feldspar and plagioclase in the (A and B) Santa Terezinha and (C and D) Catingueira plutons.

Thumbnail

Figure 10.
Feldspar classification diagram for the (A) Santa Terezinha pluton and (B) Catingueira pluton.

Thumbnail

Figure 11.
(A) Backscatter electron images of zircon grains from sample PUR-02D. (B) Concordia plot for the PUR-02D zircon spots with a lower 5% discordance displaying the main age of 625 ± 7 Ma.

Thumbnail

Table 1.
Major representative element chemical analyses for the Santa Terezinha pluton. Table of average of the obtained values.

Thumbnail

Table 2.
Representative chemical analyses for the Catingueira pluton. Table of average obtained values.

Thumbnail

Table 3.
LA-MC-ICP-MS U-Pb data used for U-Pb age calculation in the Santa Terezinha pluton.

Figure 1. (A) Pre-drift reconstruction of South America-Africa exhibiting the Amazonian (AC), São Francisco (SFC), West African (WAC), and Congo (CC) Cratons, Brasiliano-Pan-African belts, and Andean Belt. The black square represents the Borborema Province; (B) Schematic map displaying the tectonic domains of the Borborema Province (northern, central, and southern) and the main shear zones: SSZ (Sobral Shear Zone); SPSZ (Senador Pompeu Shear Zone); PSZ (Patos Shear Zone); WPeSZ (West Pernambuco Shear Zone), and EPeSZ (East Pernambuco Shear Zone). The red square represents the study area; (C) Schematic geological map of the southern PSZ, displaying the Paleoproterozoic gneisses, migmatites and amphibolites of the basement, supracrustal rocks and Neoproterozoic granites and granodiorites (CAT-Catingueira pluton, ST-Santa Terezinha pluton). The locations of field mapping points (yellow dots), geochronological (blue dot), and EBSD samples (red stars) are shown. Regional units and lithological contacts compiled and modified from Brito Neves et al. (2003Brito Neves B.B., Passarelli C.R., Basei M.A.S., Santos E.J. 2003. Idades U-Pb em zircão de alguns granitos clássicos da Província Borborema. Geologia USP. Série Científica, 3:25-38. https://doi.org/10.5327/S1519-874X2003000100003
https://doi.org/https://doi.org/10.5327/... ), Archanjo et al. (2008Archanjo C.J., Hollanda M.H.B.M., Rodrigues S.W.O., Brito Neves B.B., Armstrong R. 2008. Fabrics of pre- and syntectonic granite plutons and chronology of shearzones in the Eastern Borborema, NE Brazil. Journal of Structural Geology, 30(3):310-326. https://doi.org/10.1016/j.jsg.2007.11.011
https://doi.org/https://doi.org/10.1016/... ), Hollanda et al. (2010Hollanda M.H.B.M., Archanjo C.J., Souza L.C., Armstrong R., Vasconcelos P.M. 2010. Cambrian mafic to felsic magmatism and its connections with transcurrent shear zones of the Borborema Province (NE Brazil): Implications for the late assembly of the West Gondwana. Precambrian Research, 178(1-4):1-14. https://doi.org/10.1016/j.precamres.2009.12.004
https://doi.org/https://doi.org/10.1016/... ), and Archanjo et al. (2021Archanjo C.J., Hollanda M.H.B.M., Viegas L.G.F. 2021. Late Ediacaran lateral-escape tectonics as recorded by the Patos shear zone (Borborema Province, NE Brazil). Brazilian Journal of Geology, 51(2):e20200132. https://doi.org/10.1590/2317-4889202120200132
https://doi.org/https://doi.org/10.1590/... ).

	PUR-02
		K-feldspar			Plagioclase
	Bulk Composition (XRF)	Porphyroclasts	Recrystallized		Porphyroclasts	Recrystallized
			Core	Rim		Core	Rim
SiO₂	60.08	64.982	62.756	62.523	63.563	63.267	63.616
TiO₂	79.87	0.004	0.013	b.d.l	b.d.l	b.d.l	0.044
Al₂O₃	101.96	19.621	19.697	19.818	22.887	22.423	22.629
FeO	71.84	0.034	0.089	0.114	b.d.l	0.128	0.083
MnO	70.94	0.029	0.012	0.006	0.023	b.d.l	b.d.l
MgO	40.3	b.d.l	b.d.l	b.d.l	b.d.l	b.d.l	0.003
CaO	56.08	b.d.l	b.d.l	b.d.l	4.033	3.999	3.958
Na₂O	61.98	0.532	0.722	0.764	9.057	9.108	9.514
K₂O	94.2	14.64	15.418	15.553	0.247	0.13	0.13
Cr₂O₂	151.99	b.d.l	b.d.l	0.015	0.027	0.036	0.036
NiO	74.69	b.d.l	b.d.l	b.d.l	b.d.l	b.d.l	b.d.l
Total		99.842	98.746	98.792	99.837	99.091	99.977
OH		b.d.l	b.d.l	b.d.l	b.d.l	b.d.l	b.d.l
Si		3.012	2.928	2.913	2.818	2.826	2.809
Ti		b.d.l	0.001	b.d.l	b.d.l	b.d.l	0.001
Al		1.072	1.083	1.088	1.196	1.18	1.177
Cr		b.d.l	b.d.l	0.001	0.001	0.001	b.d.l
Fe		0.001	0.003	0.004	b.d.l	0.005	0.003
Mn		0.001	b.d.l	b.d.l	0.001	b.d.l	b.d.l
Mg		b.d.l	b.d.l	b.d.l	b.d.l	b.d.l	b.d.l
Ca		b.d.l	b.d.l	b.d.l	1.192	0.191	0.187
Na		0.048	0.065	0.069	0.779	0.789	0.814
K		0.866	0.918	0.924	0.014	0.007	0.007
An (%)					19.467	19.379	18.556
Ab (%)		5.234	6.644	6.947	79.113	79.871	80.718
Or (%)		94.766	93.356	93.053	1.42	0.75	0.726

	Catingueira pluton
		K-feldspar		Plagioclase
	Bulk Composition (XRF)	Porphyroclasts	Recrystallized	Porphyroclasts	Recrystallized
SiO₂	60.08	63.887	63.613	61.514	63.948
TiO₂	79.87	0.004	0.067	b.d.l	b.d.l
Al₂O₃	101.96	19.922	19.703	24.803	22.019
FeO	71.84	0.032	0.01	0.269	0.25
MnO	70.94	0.022	0.026	0.058	0.04
MgO	40.30	b.d.l	0.004	0.014	0.044
CaO	56.08	b.d.l	b.d.l	4.122	3.225
Na₂O	61.98	0.737	0.864	9.292	9.738
K₂O	94.20	15.58	15.437	0.156	0.285
Cr₂O₃	b.d.l	b.d.l	0.012	0.036	b.d.l
Total		100.18	99.73	100.67	99.63
Si		2.94	2.715	2.715	2.832
Ti		1.1	b.d.l	b.d.l	b.d.l
Al		b.d.l	1.29	1.29	1.149
Cr		b.d.l	0.002	0.002	b.d.l
Fe		0.001	0.001	0.001	0.009
Mn		0.001	b.d.l	b.d.l	0.002
Mg		b.d.l	b.d.l	b.d.l	0.003
Ca		b.d.l	1.192	1.192	0.153
Na		0.066	0.786	0.786	0.836
K		0.914	0.012	0.012	0.016
An (%)		0	19.377	19.377	15.222
Ab (%)		6.707	79.372	79.372	83.176
Or (%)		93.293	1.25	1.25	1.602

	Isotopic ratios
Grain spot	207Pb/206Pb	± (2σ)	207Pb/235U	± (2σ)	206Pb/238U	± (2σ)
PUR-02D-05	0.07	2.32	1.33	2.41	0.14	0.65
PUR-02D-12	0.07	3.13	1.91	3.89	0.18	2.31
PUR-02D-13	0.07	2.14	2.29	2.35	0.14	0.1
PUR-02D-27	0.06	2.21	0.84	2.6	0.1	1.36
PUR-02D-33	0.06	2.25	0.85	3.05	0.1	2.05
PUR-02D-39	0.06	2.26	0.91	2.8	0.11	1.63
PUR-02D-41	0.06	2.95	1.03	3.25	0.12	1.38

	Ages
Grain spot	207Pb/206Pb	± (2σ)	207Pb/235U	± (2σ)	206Pb/238U	± (2σ)	Rho	Th/U	Conc. (%)
PUR-02D-41	722	63	719	17	716	9	0.42	0.42	99.58
PUR-02D-05	845	48	860	14	866	5	0.27	0.38	100.79
PUR-02D-12	1,074	60	1,082	25	1,087	23	0.54	0.63	100.43
PUR-02D-13	832	44	844	13	850	8	0.42	0.43	100.74
PUR-02D-27	598	47	620	12	626	8	0.52	0.42	100.92
PUR-02D-33	617	49	624	14	625	12	0.67	0.46	100.18
PUR-02D-39	660	49	656	13	656	10	0.58	0.51	99.85

[1] *Corresponding author.

Brasil

Brasil

Deformation mechanisms, mineral chemistry and zircon U-Pb geochronological constraints in the south Patos shear zone: implications for the crustal evolution of the Borborema Province, NE Brazil

Abstract