Integrated approach using petrophysical, gravity, and magnetic data to evaluate the geothermal resources at the Rahat Volcanic Field, Saudi Arabia
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[1] Dong Li,et al. Evaluation of the geothermal parameters to decipher the thermal structure of the upper crust of the Longmenshan fault zone derived from borehole data , 2022, Geothermics.
[2] Ahmed E. Radwan. Modeling pore pressure and fracture pressure using integrated well logging, drilling based interpretations and reservoir data in the giant El Morgan oil field, Gulf of Suez, Egypt , 2021, Journal of African Earth Sciences.
[3] M. K’Orowe,et al. Simultaneous Modelling of Gravity and Magnetic Data in a Measured Heat Flux Area to Characterize Geothermal Heat Sources: A Case for Eburru Geothermal Complex, Kenya , 2021 .
[4] Hassan Nasir Mangi,et al. A Core Logging, Machine Learning and Geostatistical Modeling Interactive Approach for Subsurface Imaging of Lenticular Geobodies in a Clastic Depositional System, SE Pakistan , 2021, Natural Resources Research.
[5] D. Chiarella,et al. Combined stratigraphic-structural play characterization in hydrocarbon exploration: a case study of Middle Miocene sandstones, Gulf of Suez basin, Egypt , 2021 .
[6] Hussein M. Harbi,et al. Geothermal Resources Database in Saudi Arabia (GRDiSA): GIS model and geothermal favorability map , 2021, Arabian Journal of Geosciences.
[7] Shuangling Chen,et al. Mechanism of ultra-deep gas accumulation at thrust fronts in the Longmenshan Mountains, lower Permian Sichuan Basin, China , 2020 .
[8] H. Gu,et al. An integrated approach for the identification of lithofacies and clay mineralogy through Neuro-Fuzzy, cross plot, and statistical analyses, from well log data , 2020, Journal of Earth System Science.
[9] Fatemeh K. Saleh,et al. Geothermal Drilling: A Review of Drilling Challenges with Mud Design and Lost Circulation Problem , 2020 .
[10] R. M. Prol-Ledesma,et al. Heat flow and geothermal provinces in Mexico , 2019, Geothermics.
[11] Daniel . Bolton,et al. Geothermal Drilling and Completions: Petroleum Practices Technology Transfer , 2019 .
[12] H. Zahran,et al. Crustal structure of the northern Harrat Rahat volcanic field (Saudi Arabia) from gravity and aeromagnetic data , 2019, Tectonophysics.
[13] A. Al-amri,et al. Geothermal and Volcanic Evaluation of Harrat Rahat, Northwestern Arabian Peninsula (Saudi Arabia) , 2018, Petrogenesis and Exploration of the Earth’s Interior.
[14] T. Sisson,et al. Geologic map of the northern Harrat Rahat volcanic field, Kingdom of Saudi Arabia , 2019, Scientific Investigations Map.
[15] Essam Aboud,et al. Imaging subsurface northern Rahat Volcanic Field, Madinah city, Saudi Arabia, using Magnetotelluric study , 2018, Journal of Applied Geophysics.
[16] Z. Ahmad,et al. A Modified Approach for Volumetric Evaluation of Shaly Sand Formations from Conventional Well Logs: A Case Study from the Talhar Shale, Pakistan , 2018, Arabian Journal for Science and Engineering.
[17] J. Asfahani. Multifractal approach for delineating uranium anomalies related to phosphatic deposits in Area-3, Northern Palmyrides, Syria. , 2018, Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine.
[18] H. Dietterich,et al. Volcanic history of the northernmost part of the Harrat Rahat volcanic field, Saudi Arabia , 2018 .
[19] Charles L. Bérubé,et al. Predicting rock type and detecting hydrothermal alteration using machine learning and petrophysical properties of the Canadian Malartic ore and host rocks, Pontiac Subprovince, Québec, Canada , 2018 .
[20] Pouria Behnoud far,et al. Estimation of lost circulation amount occurs during under balanced drilling using drilling data and neural network , 2017 .
[21] K. Fajčíková,et al. Impact of Calcium and Magnesium in Groundwater and Drinking Water on the Health of Inhabitants of the Slovak Republic , 2017, International journal of environmental research and public health.
[22] Lijuan He,et al. Lithospheric thermal structure of the North China Craton and its geodynamic implications , 2016 .
[23] Abdulrahman M. Alotaibi,et al. Relationship between Curie isotherm surface and Moho discontinuity in the Arabian shield, Saudi Arabia , 2016 .
[24] H. Zahran,et al. Imaging of magma intrusions beneath Harrat Al-Madinah in Saudi Arabia , 2016 .
[25] Haibing Li,et al. Geothermal study at the Wenchuan earthquake Fault Scientific Drilling project-hole 1 (WFSD-1): Borehole temperature, thermal conductivity, and well log data , 2016 .
[26] K. Németh,et al. Synthesis of the Geoheritage Values of the Volcanic Harrats of Saudi Arabia , 2016 .
[27] Eckart Meiburg,et al. Modeling Gravity and Turbidity Currents: Computational Approaches and Challenges , 2015 .
[28] Atef A. Qaddah,et al. Magnetic and gravity data analysis of Rahat Volcanic Field, El-Madinah city, Saudi Arabia , 2015 .
[29] P. Afzal,et al. Delineation of Cu prospects utilizing multifractal modeling and stepwise factor analysis in Noubaran 1:100,000 sheet, Center of Iran , 2015, Arabian Journal of Geosciences.
[30] D. Chandrasekharam,et al. Geothermal energy resources of wadi Al-Lith, Saudi Arabia , 2014 .
[31] Sheng‐Rong Song,et al. Clay mineral anomalies in the Yingxiu–Beichuan fault zone from the WFSD-1 drilling core and its implication for the faulting mechanism during the 2008 Wenchuan earthquake (Mw 7.9) , 2014 .
[32] S. Fuchs,et al. Well-log based prediction of thermal conductivity of sedimentary successions: a case study from the North German Basin , 2014 .
[33] Aref Lashin,et al. Geothermal power potential at the western coastal part of Saudi Arabia , 2013 .
[34] Chrystel Dezayes,et al. Determination of fluid-flow zones in a geothermal sandstone reservoir using thermal conductivity and temperature logs , 2013 .
[35] M. R. Moufti,et al. Geochemistry and Sr–Nd–Pb isotopic composition of the Harrat Al-Madinah Volcanic Field, Saudi Arabia , 2012 .
[36] Raquel Jasan,et al. Heavy metal and trace element concentrations in wheat grains: assessment of potential non-carcinogenic health hazard through their consumption. , 2011, Journal of hazardous materials.
[37] N. Gegenhuber. An Improved Method to Determine Heat Production From Gamma-ray Logs , 2011 .
[38] S. Rehman,et al. Saudi Arabian Geothermal Energy Resources - an Update , 2010 .
[39] Shengbiao Hu,et al. Heat flow study at the Chinese Continental Scientific Drilling site: Borehole temperature, thermal conductivity, and radiogenic heat production , 2008 .
[40] Gordon R. J. Cooper,et al. Enhancing potential field data using filters based on the local phase , 2006, Comput. Geosci..
[41] Ben Norden,et al. Thermal conductivity and radiogenic heat production of sedimentary and magmatic rocks in the Northeast German Basin , 2006 .
[42] Richard S. Smith,et al. Interpretation of magnetic data using an enhanced local wavenumber (ELW) method , 2005 .
[43] Shafiqur Rehman,et al. Geothermal Resources of Saudi Arabia - Country Update Report , 2005 .
[44] G. Espinosa-Paredes,et al. Study on the flow production characteristics of deep geothermal wells , 2002 .
[45] Andrea Förster,et al. Analysis of borehole temperature data in the Northeast German Basin: continuous logs versus bottom-hole temperatures , 2001, Petroleum Geoscience.
[46] A. Abdul-Hadi,et al. Geophysical natural gamma-ray well logging and spectrometric signatures of south AL-Abter phosphatic deposits in Syria. , 2001, Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine.
[47] L. Rybach,et al. A simple method to determine heat production from gamma-ray logs , 1996 .
[48] M. Rider,et al. The Geological Interpretation of Well Logs , 1986 .
[49] E. Middlemost. The basalt clan , 1975 .