Curie Point Depth of the Iberian Peninsula and Surrounding Margins. A Thermal and Tectonic Perspective of its Evolution

Andrés, Juvenal; Marzán, Ignacio; Ayarza, P.; Martí, David; Palomeras, Imma; Torné, Montserrat; Campbell, Simon; Carbonell, Ramón

doi:10.1002/2017jb014994

Cited by 46 publications

(55 citation statements)

References 67 publications

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“…2) is thus assumed to be the depth to the bottom of the magnetic source (DBMS) determined from magnetic survey data. The DBMS maps a transition zone, rather than an exact depth (Haggerty, 1978), and can provide information on crustal temperatures at depths not accessible by other means (Andrés et al, 2018;Okubo et al, 1985). Regions found to have a shallower DBMS (and thus an assumed shallower CPD) are expected to have higher average temperature gradients, and, therefore, higher GHF (e.g.…”

Section: Magnetic Methods Deriving Ghf From Curie Depthmentioning

confidence: 99%

“…Regions found to have a shallower DBMS (and thus an assumed shallower CPD) are expected to have higher average temperature gradients, and, therefore, higher GHF (e.g. Aboud et al, 2011;Andrés et al, 2018;Arnaiz-Rodríguez and Orihuela, 2013;Bansal et al, 2013Bansal et al, , 2011Bhattacharyya and Leu, 1975;Guimarães et al, 2013;Li et al, 2017;Obande et al, 2014;Okubo et al, 1985;Ross et al, 2006;Salem et al, 2014;Tanaka et al, 1999;Trifonova et al, 2009).…”

Section: Magnetic Methods Deriving Ghf From Curie Depthmentioning

confidence: 99%

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Geothermal heat flow in Antarctica: current and future directions

Burton‐Johnson

Dziadek

Martín

2020

Preprint

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Abstract. Antarctic geothermal heat flow (GHF) affects the temperature of the ice sheet, determining its ability to slide and internally deform, as well as the behaviour of the continental crust. However, GHF remains poorly constrained, with few and sparse local, borehole-derived estimates, and large discrepancies in the magnitude and distribution of existing continent-scale estimates from geophysical models. We review the methods to extract GHF, compile borehole and probe-derived estimates from measured temperature profiles, and recommend the following future directions: 1) Obtain more borehole-derived estimates from the subglacial bedrock and englacial temperature profiles. 2) Estimate GHF beneath the interior of the East Antarctic Ice Sheet (the region most sensitive to GHF variation) via long-wavelength microwave emissivity. 3) Estimate GHF from inverse glaciological modelling, constrained by evidence for basal melting. 4) Revise geophysically-derived GHF estimates using a combination of Curie depth, seismic, and thermal isostasy models. 5) Integrate in these geophysical approaches a more accurate model of the structure and distribution of heat production elements within the crust, and considering heterogeneities in the underlying mantle. And 6) continue international interdisciplinary communication and data access.

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Section: Magnetic Methods Deriving Ghf From Curie Depthmentioning

confidence: 99%

Section: Magnetic Methods Deriving Ghf From Curie Depthmentioning

confidence: 99%

Geothermal heat flow in Antarctica: current and future directions

Burton‐Johnson

Dziadek

Martín

2020

Preprint

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“…7 and 2) is thus assumed to be the depth to the bottom of the magnetic source (DBMS) determined from magnetic survey data. The DBMS maps a transition zone, rather than an exact depth (Haggerty, 1978) and can provide information on crustal temperatures at depths not accessible by other means (Andrés et al, 2018;Okubo et al, 1985). Regions found to have a shallower DBMS (and thus an assumed shallower CPD) are expected to have higher average temperature gradients, and, therefore, higher GHF (e.g.…”

Section: Magnetically Derived Estimatesmentioning

confidence: 99%

Review article: Geothermal heat flow in Antarctica: current and future directions

2020

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Abstract. Antarctic geothermal heat flow (GHF) affects the temperature of the ice sheet, determining its ability to slide and internally deform, as well as the behaviour of the continental crust. However, GHF remains poorly constrained, with few and sparse local, borehole-derived estimates and large discrepancies in the magnitude and distribution of existing continent-scale estimates from geophysical models. We review the methods to estimate GHF, discussing the strengths and limitations of each approach; compile borehole and probe-derived estimates from measured temperature profiles; and recommend the following future directions. (1) Obtain more borehole-derived estimates from the subglacial bedrock and englacial temperature profiles. (2) Estimate GHF from inverse glaciological modelling, constrained by evidence for basal melting and englacial temperatures (e.g. using microwave emissivity). (3) Revise geophysically derived GHF estimates using a combination of Curie depth, seismic, and thermal isostasy models. (4) Integrate in these geophysical approaches a more accurate model of the structure and distribution of heat production elements within the crust and considering heterogeneities in the underlying mantle. (5) Continue international interdisciplinary communication and data access.

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“…The 3‐D random magnetization model is then Fourier transformed and multiplied by

{(k_{x}^{2} + k_{y}^{2} + k_{z}^{2})}^{- α / 2}

(Pilkington & Todoeschuck, ), where k x , k y , and k z are the wavenumbers in the x , y , and z directions, α is the scaling exponent of magnetization α = β +1 (Maus & Dimri, ). Here we select α=3 for 3‐D sources as commonly used by many (e.g., Andrés et al, ; Bouligand et al, ; Fedi et al, ; Li et al, , ). Subsequently, the modulated wavenumber domain model is inverse transformed into the space domain to obtain the fractal magnetization model.…”

Section: Synthetic Datamentioning

confidence: 99%

Estimation of Depth to Bottom of Magnetic Sources Using Spectral Methods: Application on Iran's Aeromagnetic Data

2020

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The effect of window size while estimating the depth to bottom of magnetic sources (DBMS) is examined on the synthetic 2‐D magnetic field data. The data are generated for 3‐D fractal magnetization models assuming different combinations of depth to the top and bottom of magnetic sources. The depths are estimated assuming an uncorrelated and correlated random distribution of sources. The depths to the top estimated for fractal distribution of sources are found within 70% of the true values for all window sizes, whereas the values for the uncorrelated random distributions are far from the real depths. The DBMS for the correlated random distribution of sources are estimated within 70–80% of the true values for the window sizes of 5 times or more of the targeted depths. The modified centroid method is found to provide better estimations as compared to scaling‐spectral peak modeling. The modified centroid method is applied to the aeromagnetic data of Iran to estimate the DBMS using a window size of 200 × 200 km2. The shallow DBMS between 12 and 20 km are obtained for the Quaternary Sabalan and Sahand volcanoes to the NW of Iran, the central and NE of central Iran, the central Zagros, NW of Tabas block, and the south of the Lut Block. The deepest DBMS of the order of 40 km is found in the Makran. The rest of Iranian Plateau is characterized by DBMS of 20 to 30 km. The shallow DBMS are found in correlation with the depth of the Ophiolites.

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Curie Point Depth of the Iberian Peninsula and Surrounding Margins. A Thermal and Tectonic Perspective of its Evolution

Cited by 46 publications

References 67 publications

Geothermal heat flow in Antarctica: current and future directions

Geothermal heat flow in Antarctica: current and future directions

Review article: Geothermal heat flow in Antarctica: current and future directions

Estimation of Depth to Bottom of Magnetic Sources Using Spectral Methods: Application on Iran's Aeromagnetic Data

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