Abbas M S, Afefe A A, Hatab E B E, et al. 2016. Vegetation-soil relationships in wadi El-Rayan protected area, western desert, Egypt. Jordan Journal of Biological Sciences, 9(2): 97–107.
Agarwal P, Dabi M, Kinhekar K, et al. 2020. Special adaptive features of plant species in response to salinity. In: Hasanuzzaman M, Tanveer M. Salt and Drought Stress Tolerance in Plants Signaling Networks and Adaptive Mechanisms. Switzerland: Springer, 53–76.
Allahgholi A, Asri Y. 2014. Changes in plant communities within the south east salt marshes of Orumieh Lake. Plant Ecophysiology, 5(15): 74–87. (in Persian)
Apaydin Z, Kutbay H G, Ozbucak T, et al. 2009. Relationships between vegetation zonation and edaphic factors in a salt-marsh community (Black Sea Coast). Polish Journal of Ecology, 57(1): 99–112.
Arevalo J R, Fernández-Lugo S, Reyes-Betancort J A, et al. 2017. Relationships between soil parameters and vegetation in abandoned terrace field vs. non-terraced fields in arid lands (Lanzarote, Spain): an opportunity for restoration. Acta Oecologica, 85: 77–84.
Asrari A, Bakhshikhaniki G H, Rahmatizadeh A. 2012. Assessment of relationship between vegetation and salt soil in Qom Province. Iranian Journal of Range and Desert Research, 19(2): 264–282. (in Persian)
Austin M P. 2005. Vegetation and environment: discontinuities and continuities. In: van der Maarel E. Vegetation Ecology. Oxford: Blackwell Publishing, 52–84.
Cao Q Q, Yang B M, Li J R, et al. 2020. Characteristics of soil water and salt associated with Tamarix ramosissima communities during normal and dry periods in a semi-arid saline environment. CATENA, 193: 104661.
Carter M R, Gregorich E G. 2008. Soil Sampling Methods of Analysis (2nd ed.). Boca Raton: CRC Press, 1224.
Cochran W G. 1977. The estimation of sample size. In: Cochran W G. Sampling Techniques (3rd ed.). New York: John Wiley & Sons, 72–86.
Czyż E A, Dexter A R. 2015. Mechanical dispersion of clay from soil into water readily-dispersed and spontaneously-dispersed clay. International Agrophysics, 29(1): 31–37.
de Martonne E. 1926. A new climatological function: the aridity index. La Météorologie, 2: 449–458. (in French)
Flowers T J, Troke P, Yeo A R. 1977. The mechanism of salt tolerance in halophytes. Annual Review of Plant Physiology, 28(1): 89–121.
Gonzalez-Alcaraz M N, Jimenez-Carceles F J, Alvarez Y, et al. 2014. Gradients of soil salinity and moisture, and plant distribution, in a Mediterranean semi-arid saline watershed: a model of soil-plant relationships for contributing to the management. CATENA, 115: 150–158.
Greig-Smith P. 1983. Quantitative Plant Ecology (3rd ed.). Oxford: Blackwell Scientific Publications, 374.
Hejcmanovā-Neźerková P, Hejcman M. 2006. A canonical correspondence analysis (CCA) of the vegetation-environment relationships in Sudanese savannah, Senegal. The South African Journal of Botany, 72(2): 256–262.
IMO. 2015. Iran Meteorological Organization Archive. [2015-09-20]. https://www.irimo.ir/eng/index.php.
Kent M. 2011. Vegetation Description and Data Analysis: A Practical Approach. New York: John Wiley & Sons, 414.
Khatibi R, Soltani S, Khodagholi M. 2017. Effects of climatic factors and soil salinity on the distribution of vegetation types containing Anabasis aphylla in Iran: a multivariate factor analysis. Arabian Journal of Geosciences, 10(2): 1–18.
Kleyer M, Dray S, Bello F, et al. 2012. Assessing species and community functional responses to environmental gradients: which multivariate methods? Journal of Vegetation Science, 23(5): 805–821.
Koull N, Chehma A. 2016. Soil characteristics and plant distribution in saline wetlands of Oued Righ, northeastern Algeria. Journal of Arid Land, 8(6): 948–959.
Magurran A E. 2004. Measuring Biological Diversity. Australia: Blackwell Science Ltd., 256.
Mokhtari-Asl A A F, Mesdaghi M, Akbarluo M, et al. 2008. Investigation on relationships between some soil characteristics and distribution of rangelands species (Case study: Eastern Azarbayjan-Marand Gherkhelar rangelands). Journal of Agricultural Sciences and Natural Resources, 15(1): 14–24. (in Persian)
Mueller-Dombois D, Ellenberg H. 1974. Aims and Methods of Vegetation Ecology. New York: Wiley & Son, 93–135.
Park H J, Hong M G, Kim J G. 2020. Effects of soil fertility and flooding regime on the growth of Ambrosia trifida. Landscape and Ecological Engineering, 16(1): 39–46.
Piernik A. 2012. Ecological Pattern of Inland Salt Marsh Vegetation in Central Europe. Poland: Nicolas Copernicus University Press, 229.
Quevedo D I, Frances F. 2008. A conceptual dynamic vegetation-soil model for arid and semiarid zones. Hydrology and Earth System Sciences, 12(5): 1175–1187.
Rengasamy P, Greene R, Ford G, et al. 1984. Identification of dispersive behaviour and the management of red-brown earths. Australian Journal of Soil Research, 22(4): 413–431.
Sahragard H P, Chahouki M Z. 2015. An evaluation of predictive habitat models performance of plant species in Hoz-e Soltan rangelands of Qom Province. Ecological Modelling, 309: 64–71.
Salama F, Ghani M A E, Tayeh N E. 2013. Vegetation and soil relationships in the inland wadi ecosystem of central Eastern Desert, Egypt. Turkish Journal of Botany, 37(3): 489–498.
Salama F, Ghani M A E, Gadallah M, et al. 2016. Characteristics of desert vegetation along four transects in the arid environment of southern Egypt. Turkish Journal of Botany, 40(1): 59–73.
Sheikhzadeh A, Bashari H, Tarkesh-Esfahani M, et al. 2019. Investigation of rangeland indicator species using parametric and non-parametric methods in hilly landscapes of central Iran. Journal of Mountain Science, 16(6): 1408–1418.
Ter Braak C J F. 1985. Correspondence analysis of incidence and abundance data: properties in terms of a unimodal response model. Journal of Biometrics, 41(4): 859–873.
Ungar I A. 1967. Vegetation-soil relationships on saline soils in Northern Kansas. American Midland Naturalist, 78(1): 98–120.
Weaver R W, Angel J S, Bottomley P S. 1994. Methods of Soil Analysis: Microbiological and Biochemical Properties. Madison: Soil Society of America, 1152.
Yang F, An F H, Ma H, et al. 2016. Variations on soil salinity and sodicity and its driving factors analysis under microtopography in different hydrological conditions. Water, 8(6): 227.
Zhang L W, Wang B C. 2016. Intraspecific interactions shift from competitive to facilitative across a low to high disturbance gradient in a salt marsh. Plant Ecology, 217(8): 959–967.