The effect of Tous fault on groundwater resources in northern parts of Mashhad plain
Subject Areas :
Mineralogy
Mohammadreza Arjmand
1
,
Abbas Kangi
2
,
Naser Hafezi moghaddas
3
1 - Department of Geology, Shahroud Branch, Islamic Azad University, Shahroud, Iran
2 - Department of Geology, Shahroud Branch, Islamic Azad University, Shahroud, Iran
3 - Department of Geology, Faculty of Sciences,
Ferdowsi University of Mashhad, Iran
Received: 2018-08-20
Accepted : 2019-01-22
Published : 2019-07-01
Keywords:
Marly bedrock,
Tous fault,
Mashhad Plain aquifer,
Active Fault,
Abstract :
Mashhad Plain affects by a series of active faults in the northern margin of the Binalud and the southern margin of the Kopet-Dagh mountain ranges. The activity of these faults forms the morphology of the stepped bedrock of the Plain. In addition, the faults’ activities in the Quaternary period are the main effective parameters in thickness and texture of aquifer deposits in Mashhad Plain. In this regard, one of the active and important faults in Mashhad Plain is Tous fault, which runs from the northwest of Mashhad Plain into the city of Mashhad. The present research aims to analyze the effect of this fault on groundwater resources in the north of Mashhad Plain. For this purpose, ancient geoelectric studies and many well logs data are gathered, interpreted and by the combination of all of the geology information a new model for groundwater resource of the area proposed. The results of this study indicate that activities of Tous fault results to the uplifting of the Neogene Marly bedrock of Mashhad Plain, which such as a barrier prevents the flow of groundwater from the northern plain to the main aquifer of Mashhad Plain, and practically has divided the alluvial aquifer of Mashhad Plain into two parts. The maximum sediment thickness can be seen adjacent to the fault in the north of the Tous region and the tomb of Ferdowsi.
References:
Aghanabati A (2004) Geology of Iran, Geological Survey of Iran, 558 p.
Alavi M (1994) Tectonic of the Zagros orogenic belt of Iran: new data and interpretations, Tectonophysics 229: 211–238.
Al-Taj M (2008) Structural Control on Groundwater Distribution and Flow in Irbid Area, North Jordan, Jordan Journal of Earth and Environmental Sciences 1: 81-88.
Ambaseys NN, Melvile CP (1982) A History of Persian Earthquakes. Cambridge University press, London.
Aydin A (2000) Fractures, faults and hydrocarbon entrapment, migration, and flow. Marine and petroleum geology 17(7): 797-814.
Azadi A, Javan-Doloei GH, Hafezi-Moghadas N, Hesami Azar KH (2009) Geological, geotechnical and geophysical characteristics of the Tous Fault located North of Mashhad, North-eastern Iran, Journal of the Earth and Space Physics 35(4): 17-34 (In persian).
Bense VF, Gleeson T, Loveless SE, Bour O, Scibek J (2013) Fault zone hydrogeology. Earth Science Reviews 127:171-192.
Ben-Zion Y, Sammis CG (2003) Characterization of fault zones. Pure and Applied Geophysics 160: 677–715.
Berberian M, Ghorashi M, Shoja-Taheri J, Talebian M (1999) Siesmotectonic and earthquake- fault hazard investigations in the Mashhad- Neyshabur region, Geological Survey of Iran, report No. 72 (In Persian).
Berberian M, Jackson JA, Qorashi M, Talebian M, Khatib M, Preistley K (2000) The 1994 Sefidabeh earthquakes in eastern Iran: blind thrusting and bedding – plane slip on a growing anticline, and active tectonics of the Sistan suture zone, Geophysical Journal International 142: 283-299.
Burbey T (2008) The influence of geologic structures on deformation due to groundwater withdrawal. Ground Water 46:202-211.
Caine JS, Forster CB (1999) Fault zone architecture and fluid flow: insight from field data and numerical modeling. Geophysical Monograph-American Geophysical Union 113: 101-128.
Caine JS, Evans JP, Forster CB (1996) Faults zone architecture and permeability structure. Geology 24(11): 1025-1028.
Cervantes A, Armienta MA (2004) Influence of faulting on groundwater quality in Valle del Mezquital, Mexico. Geofísica Internacional 43(3), 477-493.
Chester FM, Logan JM (1986) Implications for mechanical properties of brittle faults from observations of the Punchbowl fault zone California. Pure Applied Geophysics 124(1-2): 80-106.
Folch A, Mas-Pla J (2008) Hydrogeological interactions between fault zones and alluvial aquifers in regional flow systems. Hydrological Processes: An International Journal 22(17): 3476–3487.
Forster CB, Evans JP (1991) Hydrogeology of thrust faults and crystalline thrust sheets: results of combined field and modeling studies. Geophysics research letters 18:979-982.
Geraud Y, Diraison M, Orellana N (2006) Fault zone geometry of mature active normal fault: a Potential high Permeability channel (Pirgaki fault, Corinth rift, Greece). Tectonophysics 264: 61-76.
Goldscheider N, Meiman J, Pronk M, Smart C (2008) Tracer tests in karst hydrogeology and speleology. International Journal of speleology 37(1), 27-40.
Hafezi-Moghadas N, Azadi A, Rahimi B (2017) Identifying of the route and determining the setback of southern fault of Mashhad, Research project of Ferdowsi university and engineering construction organization of Khorasan Razavi.
Hashemi N (2010) Surveying the relationship between faults and large-scale fractures and the quality and abundance status of groundwater resources in Semnan province, The First Iranian National Conference on Applied research in Water Resources, Kermanshah , Kermanshah University of Technology , (In Persian).
Hung LQO, Batelaan DN, De Smedt F (2004) Lineament analysis for the groundwater in karst fractured rocks in the suoimuoi karst catchment, In Proceedings of the International Transdisciplinary Conference on Development and Conservation of Karst Regions, Hanoi, Vietnam 13-18.
Jourde H, Flodin EA, Aydin A, Durlofsky LJ, Wen XH (2002) Computing permeability of fault zones in eolian sandstone from outcrop measurements. AAPG Bulletin 86 (7): 1187- 1200.
Khorsandi-Aghai A, Miyata T, Ghoreishi H (2008) The interaction between water resources and faults: a Case study of Lar valley in northeast Tehran, International Journal of Geology 2(3): 38-42.
Kim YS, Peacock DCP, Sanderson DJ (2004) Fault damage zones. Journal of Structural Geology 26: 503–517.
Koch M, Mather PM (1997) Lineament mapping for groundwater resource assessment: a comparison of digital Synthetic Aperture Radar (SAR) imagery and stereoscopic Large Format Camera (LFC) photographs in the Red Sea Hills, Sudan. International Journal of Remote Sensing 18 (7): 1465-1482.
Lippmann MJ, Truesdell AH, Pruess K (2000) The control of fault on the hydrology of the Cerro Prieto III area, Twenty-Fifth Workshop on Geothermal Reservoir Engineering Stanford University, Stanford, California, SGP-TR 165: 24-26.
Mayer A, May W, lukharila C, ziehl J (2007) Estimation of fault-zone conductance by calibration of a regional groundwater flow model: Desert Hot Springs, California. Hydrogeology Journal 15: 1093- 1106.
Meijerink AMJ (2007) Remote Sensing Applications to Groundwater. IHP-VI, Series on Groundwater.
Mighan N, Sharifi H (2018) Active Fault map of Mashhad City, Geological Survey of Iran North-East Territory, (in Persian).
Nabavi, MH (1976) An Introduction to geology of Iran. Geological Survey of Iran, Tehran. (In Persian)
Naderi-Mighan N, Sharifi H (2018) Active Fault map of Mashhad City, Geological Survey of Iran North-East Territory.
Natal’in BA, Sengör AMC (2005) Late Palaeozoic to Triassic evolution of the Turan and Scythian platforms; the pre-history of the Palaeo-Tethyan closure. Tectonophysics 404: 175-202.
Rana SS (1998) Application of Directional Filtering in Lineament Mapping for Groundwater Prospecting Around Bhinmal- A Semi-Arid Part of Thar Desert. Journal of the Indian Society of Remote Sensing 26(1-2): 35-44.
Saba N, Skooi B (2012) Two-dimensional modeling of very low frequency (VLF) data along a profile region, Iran, Journal of The Earth and space physics 38(2): 149-156, (In Persian).
Sander P (2007) Lineaments in groundwater exploration: a review of applications and limitations, Hydrogeology Journal 15: 71-74.
Seaton WJ, Burbey TJ (2005) Influence of Ancient Thrust Faults on the Hydrogeology of the Blue Ridge Province.
Travaglia (1988) Ground water exploration by satellite remote sensing on the Syrian Arab Republic. RSC services 76, FAO International43 (3): 477-493.
Williams NH, Lee M (2008) Ireland at risk - Possible implications for groundwater resources of climate change. Geological Survey of Ireland 13: 1-28.
Zaigham NA, Aburizaiza OS, Nayyer ZA, Mehar GA, Siddiq A, Noor S (2003) Satellite Tech-Identification of Groundwater Offshore Springs in the Red Sea along Jeddah-Rabigh Costal Belt: A Case of Fault-Zone-Aquifers in Crystalline Rocks of Arabian Shield.