Miocene Tholeiitic and Calk-Alkaline Magmatism From the Northern Colombian Andes – Implications for Magma Petrogenesis in the Northern Volcanic Zone

“…Therefore, the emplacement of these magmatic intrusions requires a breakoff in the Caribbean slab east of the PCA at about 15 Ma. This interpretation is corroborated by the regional trend of Miocene magmatism related to Pacific plates subduction (Figures 8f and 8g) and additionally, by the adakitic signature of these Miocene bodies (Weber et al, 2020). The latter could be related to the subduction of the active Sandra spreading center and to the complicated Nazca plate geometry behind the CSP triple junction.…”

“…This condition could explain the weak nature of these velocity anomalies and the scarce seismicity east of the PCA (Figure 4b). Additionally, this interpretation is supported by the adakitic magmatic signature in eastern Panama (de Boer et al., 1988; Gutscher et al., 2000); the faster eastward motion of the Panama isthmus as compared to the Caribbean plate (as result of the Nazca slab pushing from below) (Figures 9a and 10g); the Miocene subduction‐related magmatism north of 5.5°N (Weber et al., 2020), and the geometrical origin of the Farallon plate boundary as an Aleutian type margin (Cardona et al., 2018).…”

“…Clear evidence that points to a slab breakoff beneath the NWSA margin is the development of Miocene arc‐related magmatism in close proximity to the suture zone between the PCA and SA (Figures 3b, 8g, and 10d). These magmatic intrusions, ranging in age from 15 to 7 Ma (e.g.,Leal‐Mejía et al., 2019), with heterogeneous compositions including tholeiitic, calc–alkaline, and shoshonitic signatures (Weber et al., 2020), have been regarded as originating from fluids from the Nazca slab (Wagner et al., 2017; Weber et al., 2020). Under the premise of an existing Caribbean slab (Figures S3f–S3h in Supporting Information ), however, this magmatism would not be possible, as the fluids rising from the Nazca plate would be stopped by the overlaying Caribbean slab (which may have been subducting shallower than 50 km) (Figures S3f–S3h in Supporting Information ).…”

“…We employ the paleogeographic reconstruction of the plate margins and the spatiotemporal distribution of Cenozoic arc magmatism. We used the recently published Cenozoic arc magmatism records along the Colombian margin (Barbosa‐Espitia et al., 2019; Cardona et al., 2018; Lara et al., 2013; Leal‐Mejía et al., 2019; Marín‐Cerón et al., 2019; Wagner et al., 2017; Weber et al., 2020), the Ecuadorian Andes (Schütte et al., 2010) and the Panamanian isthmus (Lissinna, 2005; Montes et al., 2012; Rooney et al., 2015; Wegner et al., 2011). The resulting geometric models were integrated with published evidence of deformation in the upper plate, which allowed us to identify possible correlations between the regional plate geodynamics and first‐order phases of deformation in the Northern Andes during the Cenozoic (Table S1 in Supporting Information ).…”

Kinematics and Convergent Tectonics of the Northwestern South American Plate During the Cenozoic

“…Therefore, the emplacement of these magmatic intrusions requires a breakoff in the Caribbean slab east of the PCA at about 15 Ma. This interpretation is corroborated by the regional trend of Miocene magmatism related to Pacific plates subduction (Figures 8f and 8g) and additionally, by the adakitic signature of these Miocene bodies (Weber et al, 2020). The latter could be related to the subduction of the active Sandra spreading center and to the complicated Nazca plate geometry behind the CSP triple junction.…”

“…This condition could explain the weak nature of these velocity anomalies and the scarce seismicity east of the PCA (Figure 4b). Additionally, this interpretation is supported by the adakitic magmatic signature in eastern Panama (de Boer et al., 1988; Gutscher et al., 2000); the faster eastward motion of the Panama isthmus as compared to the Caribbean plate (as result of the Nazca slab pushing from below) (Figures 9a and 10g); the Miocene subduction‐related magmatism north of 5.5°N (Weber et al., 2020), and the geometrical origin of the Farallon plate boundary as an Aleutian type margin (Cardona et al., 2018).…”

“…Clear evidence that points to a slab breakoff beneath the NWSA margin is the development of Miocene arc‐related magmatism in close proximity to the suture zone between the PCA and SA (Figures 3b, 8g, and 10d). These magmatic intrusions, ranging in age from 15 to 7 Ma (e.g.,Leal‐Mejía et al., 2019), with heterogeneous compositions including tholeiitic, calc–alkaline, and shoshonitic signatures (Weber et al., 2020), have been regarded as originating from fluids from the Nazca slab (Wagner et al., 2017; Weber et al., 2020). Under the premise of an existing Caribbean slab (Figures S3f–S3h in Supporting Information ), however, this magmatism would not be possible, as the fluids rising from the Nazca plate would be stopped by the overlaying Caribbean slab (which may have been subducting shallower than 50 km) (Figures S3f–S3h in Supporting Information ).…”

“…We employ the paleogeographic reconstruction of the plate margins and the spatiotemporal distribution of Cenozoic arc magmatism. We used the recently published Cenozoic arc magmatism records along the Colombian margin (Barbosa‐Espitia et al., 2019; Cardona et al., 2018; Lara et al., 2013; Leal‐Mejía et al., 2019; Marín‐Cerón et al., 2019; Wagner et al., 2017; Weber et al., 2020), the Ecuadorian Andes (Schütte et al., 2010) and the Panamanian isthmus (Lissinna, 2005; Montes et al., 2012; Rooney et al., 2015; Wegner et al., 2011). The resulting geometric models were integrated with published evidence of deformation in the upper plate, which allowed us to identify possible correlations between the regional plate geodynamics and first‐order phases of deformation in the Northern Andes during the Cenozoic (Table S1 in Supporting Information ).…”

Kinematics and Convergent Tectonics of the Northwestern South American Plate During the Cenozoic