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Reduction of the wind erosion potential in dried-up lakebeds using artificial biocrusts

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Abstract

The artificial creation of biocrusts can be a rapid and pervasive solution to reduce wind erosion potential (WEP) in dried-up lakes (e.g., Lake Urmia). So, in this study, we created a biocrust by the inoculation of bacteria and cyanobacteria on trays filled by soils collected from the dried-up bed of Lake Urmia, Iran, to reduce WEP in laboratory conditions. We used the wind erodible fraction of soil (EF) and soil crust factor (SCF) equations to calculate the WEP of the treated soils. EF and SCF were decreased (p < 0.05) through applying the co-inoculation of bacteria and cyanobacteria by 5.6% and 10.57%, respectively, as compared to the control; also, the “cyanobacteria alone” inoculation decreased EF by 3.9%. Our results showed that the artificial biocrusts created by soil inoculation, especially with the co-using of bacteria and cyanobacteria, significantly reduced the WEP of a newly dried-up lakebed. Furthermore, we found that inoculation decreased the WEP of the study soil by increasing the soil organic matter content from 3.7 to 5 fold. According to scanning electron microscopy images, the inoculated microorganisms, especially cyanobacteria, improved soil aggregation by their exopolysaccharides and filaments; thus, they can be used with other factors to estimate the soil erodibility in well-developed biocrusts. The inoculation technique could be considered as a rapid strategy in stabilizing lakebeds against wind force. However, it should be confirmed after additional experiments using wind tunnels under natural conditions.

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References

  • Ahmady-Birgani H, Agahi E, Ahmadi S J, Erfanian M (2018). Sediment source fingerprinting of the Lake Urmia sand dunes. Sci Rep, 8(1): 206

    Article  Google Scholar 

  • Ansari S, Fatma T (2016). Cyanobacterial polyhydroxybutyrate (PHB): screening, optimization and characterization. PLoS One, 11(6): e0158168

    Article  Google Scholar 

  • Avecilla F, Panebianco J E, Buschiazzo D E (2015). Variable effects of saltation and soil properties on wind erosion of different textured soils. Aeolian Res, 18: 145–153

    Article  Google Scholar 

  • Belnap J, Walker B J, Munson S M, Gill R A (2014). Controls on sediment production in two US deserts. Aeolian Res, 14: 15–24

    Article  Google Scholar 

  • Belnap J, Wilcox B P, Van Scoyoc M W, Phillips S L (2013). Successional stage of biological soil crusts: an accurate indicator of ecohydrological condition. Ecohydrology, 6(3): 474–482

    Article  Google Scholar 

  • Borrelli P, Ballabio C, Panagos P, Montanarella L (2014). Wind erosion susceptibility of European soils. Geoderma, 232–234: 471–478

    Article  Google Scholar 

  • Borrelli P, Panagos P, Ballabio C, Lugato E, Weynants M, Montanarella L (2016). Towards a pan—European assessment of land susceptibility to wind erosion. Land Degrad Dev, 27(4): 1093–1105

    Article  Google Scholar 

  • Bullard J E, Ockelford A, Strong C L, Aubault H (2018). Impact of multi-day rainfall events on surface roughness and physical crusting of very fine soils. Geoderma, 313: 181–192

    Article  Google Scholar 

  • Chamizo S, Mugnai G, Rossi F, Certini G, De Philippis R (2018). Cyanobacteria inoculation improves soil stability and fertility on different textured soils: gaining insights for applicability in soil restoration. Front Environ Sci, 6: 49

    Article  Google Scholar 

  • Chepil W S (1950). Properties of soil which influence wind erosion: I. the governing principle of surface roughness. Soil Sci, 69(2): 149–162

    Article  Google Scholar 

  • Chepil W S, Woodruff N P (1954). Estimations of wind erodibility of field surfaces. J Soil Water Conserv, 9: 257–265

    Google Scholar 

  • Colazo J C, Buschiazzo D E (2010). Soil dry aggregate stability and wind erodible fraction in a semiarid environment of Argentina. Geoderma, 159(1–2): 228–236

    Article  Google Scholar 

  • Costa O Y A, Raaijmakers J M, Kuramae E E (2018). Microbial extracellular polymeric substances: ecological function and impact on soil aggregation. Front Microbiol, 9: 1636

    Article  Google Scholar 

  • Cutler N A, Belyea L R, Dugmore A J (2008). The spatiotemporal dynamics of a primary succession. J Ecol, 96(2): 231–246

    Article  Google Scholar 

  • Danesh-Yazdi M, Ataie-Ashtiani B (2019). Lake Urmia crisis and restoration plan: planning without appropriate data and model is gambling. J Hydrol (Amst), 576: 639–651

    Article  Google Scholar 

  • de Oro L A, Colazo J C, Avecilla F, Buschiazzo D E, Asensio C (2019). Relative soil water content as a factor for wind erodibility in soils with different texture and aggregation. Aeolian Res, 37: 25–31

    Article  Google Scholar 

  • Duniway M C, Pfennigwerth A A, Fick S E, Nauman T W, Belnap J, Barger N N (2019). Wind erosion and dust from US drylands: a review of causes, consequences, and solutions in a changing world. Ecosphere, 10(3): e02650

    Article  Google Scholar 

  • Farebrother W, Hesse P P, Chang H C, Jones C (2017). Dry lake beds as sources of dust in Australia during the Late Quaternary: a volumetric approach based on lake bed and deflated dune volumes. Quat Sci Rev, 161: 81–98

    Article  Google Scholar 

  • Fan B, Zhou Y, Ma Q, Yu Q, Zhao C, Sun K (2018). The bet-hedging strategies for seedling emergence of Calligonum mongolicum to adapt to the extreme desert environments in northwestern China. Front Plant Sci, 9: 1167

    Article  Google Scholar 

  • Fryrear D W, Bilbro J D, Saleh A, Schomberg H, Stout J E, Zobeck T M (2000). RWEQ: improved wind erosion technology. J Soil Water Conserv, 55(2): 183–189

    Google Scholar 

  • Fryrear D W, Krammes C A, Williamson D L, Zobeck T M (1994). Computing the wind erodible fraction of soils. J Soil Water Conserv, 49(2): 183–188

    Google Scholar 

  • Gao L, Bowker M A, Xu M, Sun H, Tuo D, Zhao Y (2017). Biological soil crusts decrease erodibility by modifying inherent soil properties on the Loess Plateau, China. Soil Biol Biochem, 105: 49–58

    Article  Google Scholar 

  • Garbeva P, Tyc O, Remus-Emsermann M N P, van der Wal A, Vos M, Silby M, de Boer W (2011). No apparent costs for facultative antibiotic production by the soil bacterium Pseudomonas fluorescens Pf0-1. PLoS One, 6(11): e27266

    Article  Google Scholar 

  • Gillette D A, Adams J, Endo A, Smith D, Kihl R (1980). Threshold velocities for input of soil particles into the air by desert soils. J Geophys Res Oceans, 85(C10): 5621–5630

    Article  Google Scholar 

  • Janssen P H, Yates P S, Grinton B E, Taylor P M, Sait M (2002). Improved culturability of soil bacteria and isolation in pure culture of novel members of the divisions Acidobacteria, Actinobacteria, Proteobacteria, and Verrucomicrobia. Appl Environ Microbiol, 68(5): 2391–2396

    Article  Google Scholar 

  • Jiang C, Zhang H, Zhang Z, Wang D (2019). Model-based assessment soil loss by wind and water erosion in China’s Loess Plateau: dynamic change, conservation effectiveness, and strategies for sustainable restoration. Global Planet Change, 172: 396–413

    Article  Google Scholar 

  • Kheirfam H (2020). Increasing soil potential for carbon sequestration using microbes from biological soil crusts. J Arid Environ, 172: 104022

    Article  Google Scholar 

  • Kheirfam H, Roohi M (2020). Accelerating the formation of biological soil crusts in the newly dried-up lakebeds using the inoculation-based technique. Sci. Total Environ, 706: 136036

    Article  Google Scholar 

  • Kheirfam H, Sadeghi S H R, Homaee M, Zarei Darki B (2017a). Quality improvement of an erosion-prone soil through microbial enrichment. Soil Tillage Res, 165: 230–238

    Article  Google Scholar 

  • Kheirfam H, Sadeghi S H R, Zarei Darki B, Homaee M (2017b). Controlling rainfall-induced soil loss from small experimental plots through inoculation of bacteria and cyanobacteria. Catena, 152: 40–46

    Article  Google Scholar 

  • Le Bissonnais Y (2016). Aggregate stability and assessment of soil crustability and erodibility: I. theory and methodology. Eur J Soil Sci, 67(1): 11–21

    Article  Google Scholar 

  • Loeppert R H, Suarez D L (1996)C Carbonate and gypsum. In: Bigham JM, editor. Methods of soil analysis, part 3—chemical methods. Madiscon: American Society of Agronomy, 437–474

    Google Scholar 

  • López M V, de Dios Herrero J M, Hevia G G, Gracia R, Buschiazzo D E (2007). Determination of the wind-erodible fraction of soils using different methodologies. Geoderma, 139(3–4): 407–411

    Article  Google Scholar 

  • Mahlmann D M, Jahnke J, Loosen P (2008). Rapid determination of the dry weight of single, living cyanobacterial cells using the Mach-Zehnder double-beam interference microscope. Eur J Phycol, 43(4): 355–364

    Article  Google Scholar 

  • Mager D M, Thomas A D (2011). Extracellular polysaccharides from cyanobacterial soil crusts: a review of their role in dryland soil processes. J Arid Environ, 75(2): 91–97

    Article  Google Scholar 

  • Maleki M, Ebrahimi S, Asadzadeh F, Emami Tabrizi M (2016). Performance of microbial-induced carbonate precipitation on wind erosion control of sandy soil. Int J Environ Sci Technol, 13(3): 937–944

    Article  Google Scholar 

  • Mugnai G, Rossi F, Felde Vincent J M N L, Colesie C, Büdel B, Peth S, Kaplan A, De Philippis R (2018). The potential of the cyanobacterium Leptolyngbya ohadii as inoculum for stabilizing bare sandy substrates. Soil Biol Biochem, 127: 318–328

    Article  Google Scholar 

  • Muñoz-Rojas M, Román J R, Roncero-Ramos B, Erickson T E, Merritt D J, Aguila-Carricondo P, Cantón Y (2018). Cyanobacteria inoculation enhances carbon sequestration in soil substrates used in dryland restoration. Sci Total Environ, 636: 1149–1154

    Article  Google Scholar 

  • Naik S N, Goud V V, Rout P K, Dalai A K (2010). Production of first and second generation biofuels: a comprehensive review. Renew Sustain Energy Rev, 14(2): 578–597

    Article  Google Scholar 

  • Pásztor L, Négyesi G, Laborczi A, Kovács T, László E, Bihari Z (2016). Integrated spatial assessment of wind erosion risk in Hungary. Nat Hazards Earth Syst Sci, 16(11): 2421–2432

    Article  Google Scholar 

  • Roncero-Ramos B, Román J R, Gómez-Serrano C, Cantón Y, Acién F G (2019). Production of a biocrust-cyanobacteria strain (Nostoc commune) for large-scale restoration of dryland soils. J Appl Phycol, 31(4): 2217–2230

    Article  Google Scholar 

  • Rossi F, De Philippis R (2015). Role of cyanobacterial exopolysaccharides in phototrophic biofilms and in complex microbial mats. Life (Basel), 5(2): 1218–1238

    Google Scholar 

  • Rossi F, Olguín E J, Diels L, De Philippis R (2015). Microbial fixation of CO2 in water bodies and in drylands to combat climate change, soil loss and desertification. N Biotechnol, 32(1): 109–120

    Article  Google Scholar 

  • Rozenstein O, Zaady E, Katra I, Karnieli A, Adamowski J, Yizhaq H (2014). The effect of sand grain size on the development of cyanobacterial biocrusts. Aeolian Res, 15: 217–226

    Article  Google Scholar 

  • Sadeghi S H R, Kheirfam H, Homaee M, Zarei Darki B, Vafakhah M (2017). Improving runoff behavior resulting from direct inoculation of soil micro-organisms. Soil Tillage Res, 171: 35–41

    Article  Google Scholar 

  • Sequeira C H, Alley M M (2011). Soil organic matter fractions as indices of soil quality changes. Soil Sci Soc Am J, 75(5): 1766–1773

    Article  Google Scholar 

  • Shahabinejad N, Mahmoodabadi M, Jalalian A, Chavoshi E (2019). The fractionation of soil aggregates associated with primary particles influencing wind erosion rates in arid to semiarid environments. Geoderma, 356: 113936

    Article  Google Scholar 

  • Stuart R K, Mayali X, Lee J Z, Craig Everroad R, Hwang M, Bebout B M, Weber P K, Pett-Ridge J, Thelen M P (2016). Cyanobacterial reuse of extracellular organic carbon in microbial mats. ISME J, 10(5): 1240–1251

    Article  Google Scholar 

  • Vacek Z, Řeháček D, Cukor J, Vacek S, Khel T, Sharma R P, Kučera J, Král J, Papaj V (2018). Windbreak efficiency in agricultural landscape of the central Europe: Multiple approaches to wind erosion control. Environ Manage, 62(5): 942–954

    Article  Google Scholar 

  • Walkley A, Black I A (1934). An examination of the Degtjareff method for determining soil organic matter, and a proposed modification of the chromic acid titration method. Soil Sci, 37(1): 29–38

    Article  Google Scholar 

  • Wang W B, Liu Y D, Li D H, Hu C X, Rao B Q (2009). Feasibility of cyanobacterial inoculation for biological soil crusts formation in desert area. Soil Biol Biochem, 41(5): 926–929

    Article  Google Scholar 

  • Whitney J W, Breit G N, Buckingham S E, Reynolds R L, Bogle R C, Luo L, Goldstein H L, Vogel J M (2015). Aeolian responses to climate variability during the past century on Mesquite Lake Playa, Mojave Desert. Geomorphology, 230: 13–25

    Article  Google Scholar 

  • Whitton B A, Potts M (2012). Introduction to the cyanobacteria. In: Whitton B A, ed. Ecology of Cyanobacteria II. Berlin: Springer, 1–13

    Chapter  Google Scholar 

  • Pagliai M, Stoops G (2010). Physical and biological surface crusts and seals. In: Stoops G, Marcelino V, Mees F, eds. Interpretation of Micromorphological Features of Soils and Regoliths. New York: Elsevier, 419–440

    Chapter  Google Scholar 

  • Yan Y, Wang X, Guo Z, Chen J, Xin X, Xu D, Yan R, Chen B, Xu L (2018). Influence of wind erosion on dry aggregate size distribution and nutrients in three steppe soils in northern China. Catena, 170: 159–168

    Article  Google Scholar 

  • Zeinoddini M, Tofighi M A, Vafaee F (2009). Evaluation of dike-type causeway impacts on the flow and salinity regimes in Urmia Lake, Iran. J Great Lakes Res, 35(1): 13–22

    Article  Google Scholar 

  • Zou X, Li J, Cheng H, Wang J, Zhang C, Kang L, Liu W, Zhang F (2018). Spatial variation of topsoil features in soil wind erosion areas of northern China. Catena, 167: 429–439

    Article  Google Scholar 

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Acknowledgments

This research was supported by the Urmia Lake Research Institute, Urmia University, Iran (No. 98/A/001), whose valuable assistance is greatly appreciated.

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Authors and Affiliations

  1. Department of Range and Watershed Management, Faculty of Natural Resources, Urmia University, Urmia, 5756151818, Iran

    Hossein Kheirfam

  2. Department of Environmental Sciences, Urmia Lake Research Institute, Urmia University, Urmia, 5756151818, Iran

    Hossein Kheirfam

  3. Microbiology Laboratory Expert, Artemia & Aquaculture Research Institute, Urmia University, Urmia, 5756151818, Iran

    Maryam Roohi

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  1. Hossein Kheirfam
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Correspondence to Hossein Kheirfam.

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Kheirfam, H., Roohi, M. Reduction of the wind erosion potential in dried-up lakebeds using artificial biocrusts. Front. Earth Sci. 16, 865–875 (2022). https://doi.org/10.1007/s11707-021-0951-4

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