Reconstruction of the Exhumed Mantle Across the North Iberian Margin by Crustal-Scale 3-D Gravity Inversion and Geological Cross Section

Abstract. The Cantabrian Mountains have been interpreted as a Paleozoic basement block uplifted during an Alpine deformation event that led to the partial closure of the Bay of Biscay and the building of the Pyrenean range in the Cenozoic. A detailed interpretation of deep seismic reflection profile ESCIN-2 and the two-dimensional seismic modelling of the data allowed us to construct a N–S geological cross section along the southern border of the Cantabrian Mountains and the transition to the Duero Cenozoic foreland basin, highlighting the Alpine structure. The proposed geological cross section has been constrained by all geophysical data available, including a 2-D gravity model constructed for this study as well as refraction and magnetotelluric models from previous studies. A set of south-vergent thrusts dipping 30 to 36° to the north, cut the upper crust with a ramp geometry and sole in the boundary with the middle crust. These thrusts are responsible for the uplift and the main Alpine deformation in the Cantabrian Mountains. A conspicuous reflective Moho shows that the crust thickens northwards from the Duero basin, where subhorizontal Moho is 32 km deep, to 47 km in the northernmost end of ESCIN-2, where Moho dips to the north beneath the Cantabrian Mountains. Further north, out of the profile, Moho reaches a maximum depth of 55 km, according to wide-angle/refraction data. ESCIN-2 indicates the presence of a tectonic wedge of the crust of the Cantabrian margin beneath the Cantabrian Mountains, which is indented from north to south into the delaminated Iberian crust, forcing its northward subduction.

Download Full-text

Alpine tectonic wedging and crustal delamination in the Cantabrian Mountains (NW Spain)

10.5194/se-2016-23 ◽

2016 ◽

Cited By ~ 1

Author(s):

Jorge Gallastegui ◽

Javier A. Pulgar ◽

Josep Gallart

Keyword(s):

Cross Section ◽

Foreland Basin ◽

Seismic Reflection Profile ◽

Cantabrian Mountains ◽

Seismic Modelling ◽

The North ◽

Geological Cross Section ◽

Deformation Event ◽

Southern Border ◽

Detailed Interpretation

Abstract. The Cantabrian Mountains have been interpreted as a Paleozoic basement block uplifted during an Alpine deformation event that led to the partial closure of the Bay of Biscay and the building of the Pyrenean range in the Cenozoic. A detailed interpretation of deep seismic reflection profile ESCIN-2 and the two-dimensional seismic modelling of the data allowed us to construct a N-S geological cross-section along the southern border of the Cantabrian Mountains and the transition to the Duero Cenozoic foreland basin, highlighting the Alpine structure. The proposed geological cross-section has been constrained by all geophysical data available, including a 2-D gravity model constructed for this study as well as refraction and MT models from previous studies. A set of thrusts vergent to the S, dipping 30° to 36°, cut the upper crust and are responsible for the uplift and the main Alpine deformation in the Cantabrian Mountains. A conspicuous reflection Moho shows that the crust thickens northwards from the Duero basin, where subhorizontal Moho is 32 km deep, to 47 km in the northernmost end of ESCIN-2 where it is dipping to the north beneath the Cantabrian Mountains. Further north, out of the profile, Moho reaches a maximum depth of 55 km according to wide-angle/refraction data. ESCIN-2 indicates the presence of a tectonic wedge of the crust of the Cantabrian margin beneath the Cantabrian Mountains, which is indented from north to south into the delaminated Iberian crust, forcing its northwards subduction

Download Full-text

Geological study in Tal - Talekhu section of Manang District along the Besisahar – Chame Road

Bulletin of the Department of Geology ◽

10.3126/bdg.v22i0.33411 ◽

2020 ◽

Vol 22 ◽

pp. 25-28

Author(s):

Prakash Luitel ◽

Suman Panthee

Keyword(s):

Cross Section ◽

Geological Mapping ◽

Igneous Rocks ◽

Geological Cross Section ◽

Lowermost Part ◽

Migmatitic Gneiss

The section between Tal to Talekhu of Manang District lacks the detailed geological study. The geological mapping in the scale of 1:50,000 followed by the preparation of geological cross-section and lithostratigraphic column has been done in the present study. The studied area lies partially in the Higher Himalayan Crystalline and the Tibetan Tethys Sequence. The units of the Higher Himalayan Group from Tal to Talekhu consists mainly of vigorous to faintly calcareous gneiss, migmatitic gneiss, quartzite, granite, etc. They are named as the Calc. Silicate Gneiss and Paragneiss and the Orthogneiss and Granite units. The lowermost part of the Tibetan Tethys consisted of metamorphosed calcareous rocks containing silicates and feldspar, so this unit is termed as the Marble and Calc. Gneiss. The section is about 9 km in thickness and is highly deformed with presence of igneous rocks at many places.

Download Full-text

Integrated crustal–geological cross-section of Ellesmere Island

Geological Society London Special Publications ◽

10.1144/sp460.12 ◽

2017 ◽

Vol 460 (1) ◽

pp. 7-17 ◽

Cited By ~ 6

Author(s):

R. Stephenson ◽

K. Piepjohn ◽

C. Schiffer ◽

W. Von Gosen ◽

G. N. Oakey ◽

...

Keyword(s):

Cross Section ◽

Ellesmere Island ◽

Geological Cross Section

Download Full-text

Evidence for strong relations between the upper Tagus loess formation (central Iberia) and the marine atmosphere off the Iberian margin during the last glacial period

Quaternary Research ◽

10.1017/qua.2020.119 ◽

2021 ◽

pp. 1-30

Author(s):

Daniel Wolf ◽

Thomas Kolb ◽

Karolin Ryborz ◽

Susann Heinrich ◽

Imke Schäfer ◽

...

Keyword(s):

North Atlantic ◽

Moisture Transfer ◽

Sea Temperature ◽

Last Glacial ◽

Atmospheric Circulation Patterns ◽

The North ◽

Terrestrial Environments ◽

The North Atlantic ◽

Iberian Margin ◽

The Last Glacial

Abstract During glacial times, the North Atlantic region was affected by serious climate changes corresponding to Dansgaard-Oeschger cycles that were linked to dramatic shifts in sea temperature and moisture transfer to the continents. However, considerable efforts are still needed to understand the effects of these shifts on terrestrial environments. In this context, the Iberian Peninsula is particularly interesting because of its close proximity to the North Atlantic, although the Iberian interior lacks paleoenvironmental information so far because suitable archives are rare. Here we provide an accurate impression of the last glacial environmental developments in central Iberia based on comprehensive investigations using the upper Tagus loess record. A multi-proxy approach revealed that phases of loess formation during Marine Isotope Stage (MIS) 2 (and upper MIS 3) were linked to utmost aridity, coldness, and highest wind strengths in line with the most intense Greenland stadials also including Heinrich Events 3–1. Lack of loess deposition during the global last glacial maximum (LGM) suggests milder conditions, which agrees with less-cold sea surface temperatures (SST) off the Iberian margin. Our results demonstrate that geomorphological system behavior in central Iberia is highly sensitive to North Atlantic SST fluctuations, thus enabling us to reconstruct a detailed hydrological model in relation to marine–atmospheric circulation patterns.

Download Full-text