شارک

عنوان URL للمقالة


رقم المقالة : IJES-2012-1560 (R2) زيارة : 163 الصفحة: 239 - 250

10.30495/ijes.2021.1917243.1560

نوع المخطوط: ابحاث

Economic geology of the carbonate rocks from Mesozoic Alpurai group, Peshawar basin, Pakistan

الموضوعات :

Muhammad Anjum 1 ( Department of Geology, University of Peshawar, Pakistan )
Muhammad Ishfaq 2 ( Department of Geology, University of Peshawar, Pakistan )
Sibghat Ullah 3 ( Frontier Works Organization, Pakistan )
Muhammad Yaseen 4 ( Department of Geology, Abdul Wali Khan University, Marden, Pakistan )
Liaqat Ali 5 ( National Centre of Excellence in Geology, University of Peshawar, Pakistan )
Jaroslav Prsek 6 ( Faculty of Geology, Geophysics and Environmental Protection, Department of Economic Geology, Kraków, Poland )
Gohar Rehman 7 ( Department of Geology, University of Peshawar, Pakistan )

تاريخ الإرسال : 22 الثلاثاء , شعبان, 1420 تاريخ التأكيد : 22 الثلاثاء , شعبان, 1420 تاريخ الإصدار : 22 الثلاثاء , شعبان, 1420

الکلمات المفتاحية: industrial scale, Concrete mix design, Aggregate properties, Carbonates, Chemical industries,

ملخص المقالة :

This study aims at evaluating the utilization of carbonate rocks from the Bampokha (Nikanai Ghar Formation) and Sawaldher (Kashala Formation) areas in different industries. Two varieties from the Nikanai Ghar Formation, known under the trade names as Super-white and Sunny-grey, are selected for petrographic and geochemical analysis to evaluate these as a source of calcite (CaCO3), in chemical industries. Petrographically, both the varieties from Bampokha area, are calcitic marbles that exhibit heteroblastic mosaic texture. Geochemical data coupled with X-ray diffraction and petrographic analysis confirms that the Super-white variety is very high purity marble and hence meets the specifications for different chemical industries such as iron and steel industry, glass manufacturing, flue gas desulphurization, soda ash manufacturing and water purification and effluent treatment. In contrast, the high silica (4.1 wt.%) and low calcite contents (<95 wt.%), render the Sunny-grey unsuitable for chemical industries. The rock from Sawaldher quarry, exhibiting an interlocking mosaic pattern, is calcitic marble. Minor amounts of quartz, muscovite and opaque minerals also occur. Comparing the physico-mechanical properties of the aggregate from Sawaldher marble with time-honoured international standards suggests its suitability in concrete work with ordinary portland cement and asphalt. The concrete mix, designed for Class D2 concrete, has an average 28-days compressive strength value of 518 kg/cm2 and thus well above the minimum targeted strength of 425 kg/cm2 for the mentioned class, and hence further endorses that the aggregate can produce strong concretes. This study also suggests the utilization of the studied carbonate resources on industrial scale.

المصادر:


  1. Ahmad I, Jan MQ, DiPietro JA (2003) Age and Tectonic Implication of Granitoids from the Indian Plate of Northern Pakistan Journal of the Virtual Explorer 11: 21-28.
    2.
  2. Ahmad SA (2004) Geology, Geochemistry and Petro-Genesis of the Neoproterozoic Indian Shield Extension in Pakistan Ph.D. thesis, Institute of Geology, University of Punjab, Lahore, Pakistan.
    3.
  3. Aitcin PC (2003) The Durability of High-Performance Concrete: a Review. Cement and Concrete Composites 25 (4-5): 409-420.
    4.
  4. Akubulut H, Gurer C (2007) Use of Aggregates Produced from Marble Quarry Waste in Asphalt Pavements. Building and Environment 42: 1921-1930.
    5.
  5. Alexander M, Mindess S (2005), Special aggregates and special concretes, Aggregates in concrete 361-368.
    6.
  6. American Ceramics Society (1928) Standard specifications for materials, Ceramic whiting: American Ceramics Society Journal 11(6), 378p.
    7.
  7. American Concrete Institute 211.1 (1991) Standard Practice for Selecting Proportions for Normal, Heavy weight and Mass Concrete. American Concrete Institute, Farmington Hills, Michigan.
    8.
  8. American Society for Testing and Materials C 125 (2007) Standard Terminology Relating to Concrete and Concrete Aggregates, American Society for Testing and Materials, Philadelphia, Pennsylvania, USA.
    9.
  9. American Society for Testing and Materials C128, (2015) Standard Test Method for Relative Density (Specific Gravity) and Absorption of Fine Aggregate, ASTM International, West Conshohocken, P, USA.
    10.
  10. American Society for Testing and Materials C131 (2020) Standard Test Method for Resistance to Degradation of Small-Size Coarse Aggregate by Abrasion and Impact in the Los Angeles Machine, ASTM International, West Conshohocken, PA, USA.
    11.
  11. American Society for Testing and Materials C143 (2020) Standard Test Method for Slump of Hydraulic-Cement Concrete, ASTM International, West Conshohocken, PA, USA.
    12.
  12. American Society for Testing and Materials C88, (2018) Standard Test Method for Soundness of Aggregates by Use of Sodium Sulfate or Magnesium Sulfate, ASTM International, West Conshohocken, PA, USA.
    13.
  13. American Society for Testing and Materials D 692 (2003) Standard Specification for Coarse Aggregate for Bituminous Paving Mixtures, American Society for Testing and Materials, Philadelphia, Pennsylvania, USA.
    14.
  14. American Society for Testing and Materials D4791 (2019) Standard Test Method for Flat Particles, Elongated Particles, or Flat and Elongated Particles in Coarse Aggregate, ASTM International, West Conshohocken, PA, USA.
    15.
  15. American Society for Testing and Materials D5874 (2016) Standard Test Methods for Determination of the Impact Value (IV) of a Soil, ASTM International, West Conshohocken, PA, USA.
    16.
  16. Baratian M, Arian MA, Yazdi A (2018) Petrology and petrogenesis of the SiahKuh intrusive Massive in the South of KhoshYeilagh, Amazonia Investiga, 7 (17), 616-629
    17.
  17. Bell FG (2007) Engineering Geology, 2nd Edition, Butterworth-Heinemann, an Imprint of Elsevier, United Kingdom.
    18.
  18. Bina M, Arian MA, Pourkermani M, Bazoobandi MH, Yazdi A (2020) Study of the petrography and tectonic settings of sills In Lavasanat district, Tehran (north of Iran), Nexo Revista Cientifica, 33(2), 286-296.
    19.
  19. Blyth FGH, De Freitas MH (1974) ELBS and Edward Arnold; London.
    20.
  20. Bowen OE (1957) Limestone, dolomite, and lime products, in Mineral commodities of California: California Div. Mines Bulletin 176, 293-306.
    21.
  21. Boynton RS (1980) Chemistry and technology of lime and limestone. 2nd Ed. New York, John Wiley and Sons Inc., 300p.
    22.
  22. British Geological Survey (2006) Mineral Planning Factsheet: Limestone, British Geological Survey 9p.
    23.
  23. British Geological Survey (2011) Industrial Minerals, High purity limestone.
    24.
  24. British Standard Institution (1976) The Structural Use of Concrete for Retaining Aqueous Liquids, BS 5337, London, UK.
    25.
  25. British Standard Institution (1992) Specifications for Aggregates from Natural Sources for Concrete, BS 882, London, UK.
    26.
  26. Bureau of Indian Standards (1970) Indian Standard Specification for Coarse and Fine Aggregates from Natural Sources for Concrete. IS 383. New Delhi 110002, 2nd Revision, 9th Reprint September 1993.
    27.
  27. Careddu N, Marras G, Siotto G, and Orru G (2009) Recovery and reuse of marble powder conteined in marble slurry waste. In Symposium Papers of Evaluation of Marble Wastes and Decreasing Environmental Effects (M. Ayhan, A. Karakus, M. O ¨ zdemir Aydin, Eds.), Diyarbakir, Turkey, 62–69.
    28.
  28. Çetin T (2003) Marble potential, production and export of Turkey, Gazi University Journal of the Faculty of Education 23: 243-256.
    29.
  29. Chessin H, Hamilton WC, Post B (1965) Position and Thermal Parameters of Oxygen Atom in Calcite, Acta Crystallographica 18:689-693.
    30.
  30. Cox FC, McC Bridge D, Hull, JH (1977) Procedures for the Assessment of Limestone Resources, Mineral Assessment Report, Institute of Geological Sciences, No. 30.
    31.
  31. Dervos CT, Mergos JA, Iosifides AA (2005) Characterization of Insulating Particles by Dielectric Spectroscopy: Case Study for Calcium Carbonate Powders, Material Letters 59: 2842-2849.
    32.
  32. DiPietro J, Hussain A, Ahmad I, Khan MA (2000) The Main Mantle Thrust in Pakistan: its Character and Extent. Geological Society, London, Special Publications 170: 375-393.
    33.
  33. DiPietro JA, Lawrence RD (1991) Himalayan Structure and Metamorphism South of the Main Mantle Thrust, Lower Swat, Pakistan, Journal of Metamorphic Geology 9: 481-495.
    34.
  34. DiPietro JA, Pogue, KR (2004) Tectonostratigraphic Subdivisions of the Himalaya: A View from the West. Tectonics, 23, TC5001, da: 10.1029/2003TC001554, 20p.
    35.
  35. Elueze AA, Jimoh AO, Aromolaran OK (2015) Compositional characteristics and functional applications of Obajana marble deposit in the Precambrian basement complex of central Nigeria. Ife Journal of Science 17(3): 591-603.
    36.
  36. Emefurieta WO, Ekuajemi, VO (1995) Lime Products and Economic Aspects of Igbeti, Ososo and Jakura Marble Deposit in SW- Nigeria. Journal of Mining and Geology 31(1):79-89.
    37.
  37. Fahad M, Iqbal Y, Riaz M, Ubic R, Redfern S (2015) Metamorphic Temperature Investigation of Coexisting Calcite and Dolomite Marble-Examples from Nikani Ghar Marble and Nowshera Formation (Peshawar Basin, Pakistan), Journal of Earth Sciences,
    38.
  38. Fathi IS (2014) Effect of Using Crushed Limestone in Concrete Mixes as Fine Aggregate on Compressive Strength and Workability. CBEE, 40-44.
    39.
  39. Gaied M (1996) Geological and Geotechnical Study of Eocene Useful Materials from the North-Eastern Edge of the Kasserine Palaeo-Relief (Central Tunisia). Ph.D.Thesis, Faculty of Sciences of Tunis. Tunisia. 135p.
    40.
  40. Gharib-Gorgani F, Ashja-Ardalan A, Espahbod MR, Sheikhzakariaee SJ, Yazdi A (2017) Petrology of Mg-bearing Meta Ophiolite Complexes of Qaen-Gazik, Eastern Iran, National Cave Research and Protection Organization 4(1), DOI:10.21276/ambi.2017.04.1.ga01
    41.
  41. Gogte BS (1973) An Evaluation of Some Common Indian Rocks with Special Reference to Alkali Aggregate Reactions, Engineering Geology 7:135-154.
    42.
  42. Haq IU (2012) To Investigate the Suitability of Coarse Aggregate Sources Available in District Nowshera for Use in Ordinary Structural Concrete, Unpublished MS Thesis, University of Engineering and Technology, Peshawar.
    43.
  43. Harben PW (1995) Silica and quartz, The Industrial Mineral Handbook: 156-161.
    44.
  44. Harrison DJ (1992). Industrial Minerals Laboratory Manual: Limestone, British Geological Survey Technical Report WG/92/29.
    45.
  45. Harrison DJ (1993) High-purity limestones in England and Wales, Quarterly Journal of Engineering Geology 26: 293-303.
    46.
  46. Harrison DJ, Inglethorpe SDJ, Mitchell CJ, Kemp SJ, Chaodumrong P and Charusribandhu M (1998) Procedures for the rapid assessment of limestone resources. British Geological Survey Technical Report WC/98/1, 120.
    47.
  47. Hodge ET (1938). Market for Columbia River Hydroelectric Power Using Northwest Minerals: Northwest limestones. 2 v (Vol. 2). Corps of Engineers, US Army, North Pacific Division.
    48.
  48. Hussain A, DiPietro JA, Pogue KR, Ahmad I (2004) Geological Map of the 43B Degree Sheet, NWFP, Pakistan, Degree Sheet Map Series, Geological Map No. 11, Geological Survey of Pakistan.
    49.
  49. Indian Roads Congress (2000) Guidelines on Quality Systems for Roads. Special Publication, New Delhi, India.
    50.
  50. Iqbal, MM, Gondal, Choudhry, MN, Khan ZK, Ahsan, N (2009) Allai Aggregate for Rehabilitation and Reconstruction of October 8, 2005 Earthquake Affected Allai-Banan Area, NWFP, Pakistan, Geological Bulletin of Punjab University 44:43-54.
    51.
  51. Jehangir Khan M, Ghazi S, Mehmood M, Yazdi A, Naseem AA, Serwar U, Zaheer A, Ullah H (2021) Sedimentological and provenance analysis of the Cretaceous Moro formation Rakhi Gorge, Eastern Sulaiman Range, Pakistan, Iranian Journal of Earth Sciences 13 (4), 252-266
    52.
  52. Kaplan MF (1959a) Flexural and Compressive Strength of Concrete as Affected by the Properties of Coarse Aggregates, Proceeding ACI 55: 1193-1207.
    53.
  53. Khan MA, Jan MQ, Weaver BL (1993) Evolution of the Lower Arc Crust in Kohistan, N. Pakistan: Temporal Arc Magmatism Through Early, Mature and Intra-arc Rift Stages. In: Treloar P.J, Searle M.P (eds) Himalayan Tectonics, Geological Society, London, Special Publications 74: 123–138.
    54.
  54. Khan SD, Walker DJ, Hall SA, Burke KC, Shah MT, Stockli L (2009) Did Kohistan-Ladakh Island Arc Collide First with India?. Geological Society of America Bulletin 121: 366–384.
    55.
  55. Kore SD, and Vyas AK (2016) Impact of Marble Waste as Coarse Aggregate on Properties of Lean Cement Co
    56.

سند

Sanad is a platform for managing Azad University publications

الروابط

المراكز ذات الصلة

دعامة

الصفحات الرسمية

حقوق هذا الموقع الإلكتروني مملوكة لنظام SANAD Press Management. © 1442-1446

الصفحة الرئيسية| دخول| معلومات عنا| اتصل بنا|
[English] [فارسی] [en] [fa]