Water and Soil

Current Issue

By Issue

By Author

By Subject

Author Index

Keyword Index

About Journal

Aims and Scope

Publication Ethics

Indexing and Abstracting

Related Links

FAQ

Peer Review Process

Journal Metrics

News

Manuscript Structure

Article Submission Checklist

Submit Manuscript

Download guide files

Reviewer Guide

Reviewers List

Clay Mineralogy Studies of Soils Located on Different Geomorphic Surfaces in Jabalbarez-Jiroft Area

Document Type : Research Article

Authors

1 Shahid Bahonar University of Kerman

2 University of Jiroft

Abstract

Introduction: Soil and geomorphology are closely related to each other. That is why considering geomorphic concepts in soil genesis and classification studies may cause a better understanding of soil genesis processes. Paleosols with argillic horizons were investigated on stable pediment surfaces in Jiroft area, central Iran, by Sanjari et al. (2011). They found that secondary gypsum and calcium carbonate were accumulated in mantled pediments, but moving down the slope toward lowlands, salts more soluble than gypsum have been accumulated.
Clay mineralogy in soil researches helps to better studying soil genesis and development. A quantitative and qualitative study of clay minerals together with their structural composition provides valuable data on the absorption, fixation, and desorption of different cations in soils. Smectite, chlorite, illite, vermiculite, kaolinite, palygorskite, and sepiolite were reported as dominant clay minerals found in arid and semi-arid areas. The objectives of the present study are to evaluate the clay mineralogy of Jabalbarez-Jiroft soils on different geomorphic surfaces.
Materials and Methods: The study area was located in Jabalbarez, 200 Km south Kerman, Central Iran. Fig. 1 showed the exact location of study area. Soil temperature and moisture regimes of the area were thermic and aridic, respectively. Hill, rock pediment, mantled pediment and piedmont alluvial plain landforms were identified, using aerial photo interpretation, topography and geological map observation, in addition to detailed field works. Air-dried soil samples were crushed and passed through a 2-mm sieve. Routine physicochemical analyses wereperformed on the samples. Undisturbed soil samples from the Bt horizon of pedons 4, 5 and 6 were chosen for micromorphology investigations. Beside, eight samples including A and C2 horizons of pedon 1, A and Bt horizon of pedon 3, Bt and Bw horizons of pedon 4, and Bt and C horizon of pedon 5 were selected for clay mineralogy.
Results and Discussion: Argillic horizon found in mantled pediment and piedmont alluvial plain surfaces and stable hill, respectively. In thin horizons coating of clay were observed. Pedofeatures formed in this geomorphic surface, seemed to have been buried in the soil, due to the favorable conditions in terms of the time factor and the presence of moisture in the past. Fig. 2 showed clay coatings in the Bt horizon of pedons 4,5 and 6. The presence of argillic horizons in the arid climate of the research area is attributed to a more humid paleoclimate, which was also reported by Farpoor et al. (2002), Khademi and Mermut (2003), and Sanjari et al. (2011) in Rafsanjan, Isfahan and Jiroft, central Iran, respectively. Clay minerals illite, smectite, chlorite and kaolinite were identified by using X-ray diffractometer. Similar results were also obtained by Sanjari et al. (2011) in the Jiroft area. Kaolinite and illite in soils of arid and semi-arid environments of Iran have been reported with an inherited origin (Khormali and Abtahi, 2003; Sanjari et al., 2011). As the environmental conditions are not favorable for the pedogenic formation of such minerals in soils of this study area , it is proposed that they might be inherited from their parent material. Just as previously stated by other researchers that the origin of the kaolinite minerals in the dry climate regionsis due to itsinheritance from parent materials (Farpoor et al., 2002; Khormali and Abtahi, 2003). The dominant of smectite minerals in soils on stable geomorphic surfaces ofhills and mantled pediment can be cause of stable level and more moisture content in the past and the present, which may be resulted to smectite formation from illite and chlorite transformation. Also, chlorite minerals on stable surface of mantled pediment were not observed. High amount of leaching, low pH level (

Keywords

References
1- Banaei M.H. 1998. Soil moisture and temperature regimes map of Iran. (1: 2500000). Soil and Water Research Institute.
2- Bayat O., Karimzadeh H.R., and Khademi H. 2011. Clay minerals in two paleosols on geomorphic surfaces in eastern Isfahan. Iranian Journal of Crystallography and Mineralogy, 19(1): 45-58. (In Persian with English abstract)
3- Boroomand N., and Sanjari S. 2012. Impacts of climate change on soil clay mineral composition of the Jiroft region. The first desert Conference, International desert Research Center, Tehran University. (In Persian)
4- Bouyoucos G.J. 1962. Hydrometer method improved for making particle size analysis of soil. Agron. J. 54: 464-465.
5- Birkeland P.W. 1990. Soils and Geomorphology. Oxford University Press, Inc., NewYork.
6- Brady N.C. 1990. The Nature and Properties of Soils. 10th ed., Macmillan Publishing Company.
7- Dixon J.B. 1989. Kaolin and Serpentine group minerals In: J.B. Dixon, and S.B. Weed (ed.) Minerals in soil environments, Soil. Sci. Soc. Am. J. Madison. Wisconsin, 551-634.
8- Eghbal M.K., and Southard R.J. 1993. Micromorphological evidence of polygenesis of three Aridisols western Mojave Desert, California. Soil Sci. Soc. Am. J. 57: 1041-1050.
9- Elprince A.M., Mashhady A.S., and Aba-Hussein M.M. 1979. The occurrence of pedogenic palygorskite (attpulgite) in soils of Saudi Arabia. Soil Science, 128: 211–218.
10- Fanning D.S., Keramidas V.Z., and Desoky M.A. 1989. Micas. P: 551-634.In Dixon J. B., Weed S.B., "Minerals in soil environment' (2nd) SSSA. Book series. Madison. WI.
11- Farpoor M.H., Khademi H., and Eghbal M.K. 2002. Genesis and distribution palygorskite and associated clay minerals in Rafsanjan soils on different geomorphic surface. Iran Agric. Res. 21: 39-60.
12- Farpoor M.H., and Irannejad M. 2011. Soil genesis and clay mineralogy on Aliabbas River Alluvial Fan, Kerman Province. doi: 10.1007/s12517-011-0395-3.
13- Graham R.C., and Boul S.W. 1990. Soil-geomorphic relations on the Blue Ridge Front. II. Soil characteristics and pedogenesis. Soil Sci. Soc. Am. J. 54: 1188-1194.
14- Huang L., Hong J., Tan W., Hu H., Liu F., and Wang M. 2008. Characteristics of micromorphology and element distribution of ironmanganese cutans in typical soils of subtropical China. Geoderma, 146: 40-47.
15- Iran Geology Organization. 1992. Sabzevaran Geology map, (1:250000).
16- Jackson M.L. 1975. Soil Chemical Analysis-advanced Course. Univ. of Wisonsin College of Agric., Dept of Soils Sci., Madison, WI.
17- Jafari S., and Nadian H. 2015. The study of a toposequence soil series and clay mineral assemblage in some soils of Khozestan Province. J. Water Soil. 18(69): 151-164. (In Persian with English abstract).
18- Jolicoeur S., Ilde Fons P., and Bouchard M. 2000. Kaolinite and gibbsite weathering of biotite within saprolites and soils of central Virginia. Soil Sci. Soc. Am. J. 64: 1118-1129.
19- Karimi A., Khademi H., and Jalalian A. 2009. Genesis and distribution of palygorskite and associated clay minerals in soils and sediments of southern Mashhad. Irananin Journal of Crystallography and Mineralogy, 16(4): 545-558. (In Persian with English abstract).
20- Kaviani N., Khormali F., Masihabadi H., and Tazikeh H. 2014. Micromorphology and clay mineralogy of loess-derived soils of natural and cultivated land uses along a climosequence in Golestan Province. J. of Water and Soil Conservation. 21(2): 31-58. (In Persian)
21- Khademi H., and Mermut A.R. 1998. Source of palygorskite in gypsiferous aridisols and associated sediments from central Iran. Clay Miner. 33: 561-578.
22- Khademi H., and Mermut A.R. 2003. Micromorphology and classification of Argids andassociated gypsiferous Aridisols from central Iran. Catena, 54: 439–455.
23- Khormali F., and Abtahi A. 2001. Soil genesis and mineralogy of three selected regions of Fars, Bushehr and Khuzestan provinces of Iran, formed under highly calcareous conditions. Iran agricultural Research 20: 67-82.
24- Khormali F., Abtahi A., Mahmoodi S., and Stoops G. 2003. Argillic horizon development in calcareous soils of arid and semi-arid regions of Southern Iran. Catena 776: 1-29.
25- Kittrik J.A., and Hope E.W. 1963. A procedure for the particle size separation of soil for X-ray diffraction analysis. Soil Sci. Soc. 96: 312-325.
26- Moazallahi M., and Farpoor M.H. 2012. Soil Genesis and Clay Mineralogy along the Xeric-Aridic Climotoposequence in South Central Iran. J. Agr. Sci. Tech. 14: 683-696.
27- Nelson R.E. 1982. Carbonate and Gypsum. P. 181-196. In: A. L. Page et al.(ed), Methods of Soil Analysis. Part II. 2nd ed., Agron. Monogar. No: 9, ASA and SSSA. Madison, WI.
28- Nelson D.W., and Sommers L.E. 1982. Total Carbon, Organic Carbon and Organic Matter. pp. 539-577. In: A.L. Page et al., (Ed), Methods of Soil Analisis. Part II. 2nd ed., Agron. Monogar. No: 9, ASA and SSSA. Madison, WI.
29- Neyestani M., and Farpoor M.H. 2014. Genesis, clay mineralogy and micromorphology of saline-gypsiferous soils in Kheirabad playa, Sirjan. Arid Biome Scientific and Research Journal, 4(1): 65-78. (In Persian with English abstract).
30- Owliaie H.R. 2004. Genesis, clay mineralogy and micromorphology of soils of Kohgilouye Province, southwestern Iran. Ph.D. Thesis. Shiraz University, Iran. (In Persian)
31- Reid D.A., Geraham R.C., Doglaus L.A., and Amrhein C. 1996. Smectites, mineralogy and charge characteristic in arid regions. Soil Sci Soc Am J 59: 1012-1218.
32- Sanjari S., Farpour M.H., Karimian M., and Esfandyarpour I. 2011. Genesis, micromorphology and clay mineralogy of soils located on different geomorphic surfaces in Jiroft area. J. Water Soil. 25: 2. 411-425. (In Persian with English abstract)
33- Sanjari S., and Boroomand N. 2014. Clay Mineralogy Studies of Soils Located on Different Geomorphic Surfaces in Sarduieh-Jiroft Area. Iranian Journal of Soil Research, 28(1): 209-219. (In Persian with English abstract)
34- Schoeneberger P.J., Wysocki D.A., Benham E.C., and Broderson W.D. 2002. Field book for describing and sampling soils. Natonal Soil Survey Center, Natural Resources Conservation Service. U. S. Dept. of Agriculture, Lincoln, Nebraska.
35- Soil Survey Staff. 2014. Keys to soil taxonomy. 11th edition. USDA.
36- Stahr K., Kuhn J., trommler J., Papenfum K.H., Zarei M., and Singer A. 2000. Palygorskite-cemented crusts (palycretes) in southern Portugal. Aust. J. Soil Res. 38: 169-188.
37- Stoops G. 2003. Guideline for the Analysis and Description of Soil and Regolith Thin Sections. SSSA, Madison, WI.182p.
38- Zareian Gh. 1997. Genesis, classification, morphological characteristics, physico-chemical and mineralogical of soils Beyza area in Fars Province. Master's thesis, Department of Soil Science, College of Agriculture, Shiraz University. (In Persian)
Send comment about this article
CAPTCHA Image
Water and Soil
Volume 30, Issue 4 - Serial Number 48
September and October 2016
Pages 1130-1141
Files
History
  • Receive Date: 27 February 2015
  • Accept Date: 27 February 2015
  • First Publish Date: 22 October 2016
Share
How to cite
Statistics