Microtopographic characterization and influence of biological soil crusts on the roughness of the soil in the center-west of Argentina

Authors

  • Ana L Navas Romero Instituto de Ingeniería Química. Facultad de Ingeniería. UNSJ. San JuanGeobotánica y Fitogeografía. Instituto Argentino de Investigacion en Zonas Áridas (IADIZA) - CONICET. CCT Mendoza
  • Mario A Herrera Moratta Instituto de Biotecnología. Facultad de Ingeniería. UNSJ. San JuanGeobotánica y Fitogeografía. Instituto Argentino de Investigacion en Zonas Áridas (IADIZA) - CONICET. CCT Mendoza
  • Eduardo Martinez Carretero Geobotánica y Fitogeografía. Instituto Argentino de Investigacion en Zonas Áridas (IADIZA) - CONICET. CCT Mendoza
  • María C Fernandez Belmonte Dpto. Ciencias Agropecuarias-Facultad de Ingeniería y Ciencias Agropecuarias - UNSL. San Luis.
  • Maria A Duplancic Grupo de Geobotánica y Fitogeografía. Instituto de Investigación en las Zonas Áridas (IADIZA)- CCT CONICET- Mendoza.Facultad de Ciencias Exactas y Naturales - UNCuyo. Mendoza.

DOI:

https://doi.org/10.31055/1851.2372.v54.n4.24163

Keywords:

aridity, biological crusts, evapotranspiration, morphology, roughness

Abstract

Background and aims: The influence of biological soil crusts (BSC) on soil roughness is an important function of these communities at the ecosystem level. Our objective was to characterize microtopographically the different types of BSC and evaluate their effect on the roughness of the soil along three systems differentiated by their degree of aridity.

M&M: The microrelief and roughness were evaluated in three systems: semi-arid, arid, and hyper-arid; by different and complementary techniques: chain method, photographic analysis and technique of metal rods. For the first one, a block design was used, while for the other two, we worked on the types of dominant biological crusts in each system.

Results: The morphology of the BSC varied according to the type of dominant organism. The mosses had a low height and were classified as gently undulating, the cyanobacteria had more abrupt peaks, and was classified as pinnacled, and the lichens had two height frequencies and were classified as rolling. The BSC influenced the roughness in the three sites evaluated. The type of BSC that dominated influenced the level of roughness found. The hyper-arid site was the site where the BSC had the most significant impact on roughness.

Conclusions: The microtopographic variations and the increase in roughness provided by the BSC is key to understanding the dynamics of the Monte because small interruptions on the soil such as those generated by the BSC could increase water availability and decrease nutrient losses by erosion, two fundamental aspects of the functioning of these fragile systems. 

Author Biographies

  • Ana L Navas Romero, Instituto de Ingeniería Química. Facultad de Ingeniería. UNSJ. San JuanGeobotánica y Fitogeografía. Instituto Argentino de Investigacion en Zonas Áridas (IADIZA) - CONICET. CCT Mendoza

    Becaria Postdoctoral

    Instituto de Ingeniería Química

    Geobotánica y Fitogeografía

  • Mario A Herrera Moratta, Instituto de Biotecnología. Facultad de Ingeniería. UNSJ. San JuanGeobotánica y Fitogeografía. Instituto Argentino de Investigacion en Zonas Áridas (IADIZA) - CONICET. CCT Mendoza

    Becaria Postdoctoral

    Instituto de Ingeniería Química

    Geobotánica y Fitogeografía

  • Eduardo Martinez Carretero, Geobotánica y Fitogeografía. Instituto Argentino de Investigacion en Zonas Áridas (IADIZA) - CONICET. CCT Mendoza

    Investigador Independiente

    IADIZA - CONICET

  • María C Fernandez Belmonte, Dpto. Ciencias Agropecuarias-Facultad de Ingeniería y Ciencias Agropecuarias - UNSL. San Luis.

    Prof. Titular de Morfología Vegetal

  • Maria A Duplancic, Grupo de Geobotánica y Fitogeografía. Instituto de Investigación en las Zonas Áridas (IADIZA)- CCT CONICET- Mendoza.Facultad de Ciencias Exactas y Naturales - UNCuyo. Mendoza.

    Jefa de Trabajos Prácticos de Biología

References

AGUIAR, M. R., & SALA, O. E. 1994. Competition, facilitation, seed distribution and the origin of patches in a Patagonian steppe. Oikos 70: 26-34.

AMÉZQUITA, E., L. CHAVÉZ, & A. ALVAREZ. 1996. Diseño, construcción y uso de un microrelievímetro para evaluar la dinámica de la erosión en áreas de ladera. Techn. Bull. Centro Int. Agric. Trop. 9 pag.

ANTOINE, M., M. JAVAUX, & C. BIELDERS. 2009. What indicators can capture runoff-relevant connectivity properties of the micro-topography at the plot scale? Adv. Water Resour. 32: 1297–1310. https://doi.org/10.1016/j.advwatres.2009.05.006.

ARES, J., H. DEL VALLE, & A. BISIGATO. 2003. Detection of process‐related changes in plant patterns at extended spatial scales during early dryland desertification. Global Change Biology 9: 1643-1659

BATES, S. T., & GARCIA‐PICHEL, F. 2009. A culture‐independent study of free‐living fungi in biological soil crusts of the Colorado Plateau: their diversity and relative contribution to microbial biomass. Environmental microbiology 11: 56-67.

BELNAP, J. 2006. The potential roles of biological soil crusts in dryland hydrologic cycles. Hydrol. Process. 20: 3159–78. https://doi.org/10.1002/hyp.6325.

BELNAP, J. AND O. L. LANGE. 2001. "Structure and functioning of biological soil crusts: a synthesis." Biological soil crusts: structure, function, and management. Springer, Berlin, Heidelberg, 2001. 471-479.

BELNAP, J., & O.L. LANGE. 2003. Biological Soil Crust Structure and Function. 496 pp. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-56475-8_20.

BELNAP, J., J. WELTER, N. GRIMM, N. BARGER, & J. LUDWIG. 2005. “Linkages between Microbial and Hydrologic Processes in Arid and Semiarid Watersheds.” Ecology. 86 (2): 298–307. https://doi.org/10.1890/03-0567.

BERALDI‐CAMPESI, H., HARTNETT, H. E., ANBAR, A., GORDON, G. W., & GARCIA‐PICHEL, F. 2009. Effect of biological soil crusts on soil elemental concentrations: implications for biogeochemistry and as traceable biosignatures of ancient life on land. Geobiology, 7(3), 348-359

BOLKER, B.M., M.E. BROOKS, C.J. CLARK, S.W. GEANGE, J.R. POULSEN, M.H.H. STEVENS, & J.S.S. WHIT, 2009. Generalized linear mixed models: a practical guide for ecology and evolution. Trends Ecol. Evol. 24: 127–135.

BOWKER, M. A., BELNAP, J., DAVIDSON, D. W., & PHILLIPS, S. L. 2005. Evidence for micronutrient limitation of biological soil crusts: importance to arid‐lands restoration. Ecological Applications, 15(6), 1941-1951

CABRERA, A. 1971. “Fitogeografía de La República Argentina.” Bol. Soc. Argen.Bot. XIV (1–2): 1–50. http://www.scielo.org.ar/scielo.php?script=sci_serial&pid=1851-2372.

CHAMIZO, S., E. RODRÍGUEZ-CABALLERO, I. MIRALLES-MELLADO, A. AFANA, R. LÁZARO, F. DOMINGO, A. CALVO-CASES, A. SOLE-BENET, & Y. CANTÓN. 2010. “Características de Las Costras Físicas y Biológicas Del Suelo Con Mayor Influencia Sobre La Infiltración y La Erosión En Ecosistemas Semiáridos.” Pirineos. 165 (0): 69–96. https://doi.org/10.3989/Pirineos.2010.165004.

CHAMIZO, S., Y. CANTÓN, E. RODRÍGUEZ-CABALLERO, F. DOMINGO, & A. ESCUDERO.2012. “Runoff at Contrasting Scales in a Semiarid Ecosystem: A Complex Balance between Biological Soil Crust Features and Rainfall Characteristics.” J. Hydrol. 452–453: 130–38. https://doi.org/10.1016/j.jhydrol.2012.05.045.

COLESIE, C., T. ALLAN GREEN, I. HAFERKAMP, & B. BÜDEL. 2014. “Habitat Stress Initiates Changes in Composition, CO2gas Exchange and C-Allocation as Life Traits in Biological Soil Crusts.” ISME J. 8 (10): 2104–15. https://doi.org/10.1038/ismej.2014.47.

COLESIE, C., V. FELDE, & B. BÜDEL. 2016. “Composition and Macrostructure of Biological Soil Crusts.” In Biological Soil Crusts: An Organizing Principle in Drylands, edited by B. WEBER, B. BÜDEL, & J. BELNAP, 159–72. Springer, Cham. https://doi.org/10.1007/978-3-319-30214-0_9.

CRAS, 1974. Informe sobre Hidrogeología de Pedernal - N° 804. San Juan, Argentina.

DALMASSO, A., & J. MARQUEZ. 2004. “Vegetacion de La Pampa Del Acequión y Alrededores (San Juan).” Multequina 13: 15–31.

DALMASSO, A., J. MÁRQUEZ, A. ABARCA, R. MONTECCHIANI, M. ROSALES, & E. ZABALETA, 2011. Flórula del paraje de Pedernal y alrededores: Departamento Sarmiento, San Juan. INCA, San Juan, pp: 1-84

DARBOUX, F., P. DAVY, & C. GASCUEL-ODOUX. 2002. “Effect of Depression Storage Capacity on Overland-Flow Generation for Rough Horizontal Surfaces: Water Transfer Distance and Scaling.” Earth Surf. Proc. Land. 27 (2): 177–91. https://doi.org/10.1002/esp.312.

DE FINA, A. 1992. “Aptitud Agroclimática de La República Argentina.” 402 pag. Buenos Aires.

DI RIENZO, J., M. BALZARINI, L. GONZALEZ, F. CASANOVES, M. TABLADA, & C.W. ROBLEDO. InfoStat/L software estadístico versión 2018. Universidad Nacional de Córdoba (FCA-UNC)[Internet]. 2010.

EVANS, R. D., & J. R. JOHANSEN.1999. "Microbiotic crusts and ecosystem processes." Critical Reviews in Plant Sciences 18.2 (1999): 183-225.

GARCIA-PICHEL, F., S.L. JOHNSON, D. YOUNGKIN, & BELNAP, J. 2003. Small-scale vertical distribution of bacterial biomass and diversity in biological soil crusts from arid lands in the Colorado Plateau. Microbial Ecology, 46(3), 312-321

GOVERS, G., I. TAKKEN, & K. HELMING. 2000. “Soil Roughness and Overland Flow.” Agronomie. 20 (2): 131–46. https://doi.org/10.1051/agro:2000114.

ISSA, O., J. TRICHET, C. DÉFARGE, A. COUTÉ, & C. VALENTIN. 1999. “Morphology and Microstructure of Microbiotic Soil Crusts on a Tiger Bush Sequence (Niger, Sahel).” Catena. 37 (1–2): 175–96. https://doi.org/10.1016/S0341-8162(99)00052-1.

JOHNSON, S. L., S. NEUER, & F. GARCIA‐PICHEL. 2007. Export of nitrogenous compounds due to incomplete cycling within biological soil crusts of arid lands. Environmental Microbiology, 9(3), 680-689.

JONES, C. G., J.H. LAWTON, & M. SHACHAK. 1997. Positive and negative effects of organisms as physical ecosystem engineers. Ecology, 78(7), 1946-1957.

KIDRON, G. 2007. “Millimeter-Scale Microrelief Affecting Runoff Yield over Microbiotic Crust in the Negev Desert.” Catena. 70 (2): 266–73. https://doi.org/10.1016/j.catena.2006.08.010.

KIDRON, G., A. VONSHAK, I. DOR, S. BARINOVA, & A. ABELIOVICH. 2010. “Properties and Spatial Distribution of Microbiotic Crusts in the Negev Desert, Israel.” Catena. 82 (2): 92–101. https://doi.org/10.1016/j.catena.2010.05.006.

KIDRON, G., A. YAIR, A. VONSHAK, & A. ABELIOVICH. 2003. “Microbiotic Crust Control of Runoff Generation on Sand Dunes in the Negev Desert.” Water Resour. Res. 39 (4). https://doi.org/10.1029/2002WR001561.

LAN, S., L. WU, D. ZHANG, & C. HU. 2012. “Composition of Photosynthetic Organisms and Diurnal Changes of Photosynthetic Efficiency in Algae and Moss Crusts.” Plant Soil. 351 (1–2): 325–36. https://doi.org/10.1007/s11104-011-0966-9.

MARTINEZ CARRETERO, E., & A. DALMASSO. 1992. “Litter Yield in Shrubs of Larrea in the Andean Piedmont of Mendoza, Argentina.” Vegetatio. 101 (1): 21–33. https://doi.org/10.1007/BF00031912.

NAGY M.L., A. PEREZ, & F. GARCIA-PICHEL. 2005. The prokaryotic diversity of biological soil crusts in the Sonoran Desert (Organ Pipe Cactus National Monument, AZ). FEMS Microbiol Ecol 54:233–245

NORTE, F., & S. SIMONELLI. 2010. “Características Climáticas Del Piedemonte Precordillerano Del Norte de Mendoza y Sur de San Juan.” In Amenazas Naturales de Origen Hídrico En El Centro-Oeste Árido de Argentina, 91–109. San Juan, Argentina: Editorial Fundacion Universidad Nacional de San Juan.

NOY-MEIR, I. 1973. “Desert Ecosystems: Environment and Producers.” Annu. Rev. Ecol. Syst. 4 (1): 25–51. https://doi.org/10.1146/annurev.es.04.110173.000325.

PASTRÁN, G., E. MARTINEZ CARRETERO, M. MAMANI, A. VICH, & V. SÁNCHEZ.2011. “Dinámica Eólica e Hídrica En El Sistema de Médanos Grandes , SE de San Juan , Argentina.” Multequina 20: 15–26.

REGAIRAZ, A, G. SUVIRES, & W. SIMON.1987. “Síntesis Geomorfológica Regional de La Provincia de San Juan. República Argentina.” In Actas III, X Congreso Geológico Argentino.

REGAIRAZ, M. 2000. “Suelos de Mendoza.” In Argentina. Recurso y Problemas Ambientales de La Zona Árida. Provincia de Mendoza, San Juan y La Rioja 59-62, edited by E. ABRAHAM & F. RODRÍGUEZ MARTÍNEZ. Universidades y Centros de Investigación de la Región Andina Argentina.

RIPLEY B., B. VENABLES, D.M. BATES, K. HORNIK, A. GEBHARDT, & D. FIRTH, 2015. Package ‘MASS’. Available at cran.r‐project.org/web/packages/MASS.

RODRÍGUEZ-CABALLERO, E., M. AGUILAR, Y. CANTÓN, S. CHAMIZO, & F. AGUILAR.2015. “Swelling of Biocrusts upon Wetting Induces Changes in Surface Micro-Topography.” Soil Biol.Biochem.82: 107–11. https://doi.org/10.1016/j.soilbio.2014.12.010.

RODRÍGUEZ-CABALLERO, E., Y. CANTÓN, & V. JETTEN.2015. “Biological Soil Crust Effects Must Be Included to Accurately Model Infiltration and Erosion in Drylands: An Example from Tabernas Badlands.” Geomorphology. 241: 331–42. https://doi.org/10.1016/j.geomorph.2015.03.042.

RODRÍGUEZ-CABALLERO, E., Y. CANTÓN, S. CHAMIZO, A. AFANA, & A. SOLÉ-BENET. 2012. “Effects of Biological Soil Crusts on Surface Roughness and Implications for Runoff and Erosion.” Geomorphology. 145–146: 81–89. https://doi.org/10.1016/j.geomorph.2011.12.042.

ROIG, F. 1976. “Las Comunidades Vegetales Del Piedemonte de La Precordillera de Mendoza.” Ecosur 3 (5): 1–45.

SUVIRES, G. 1987. “Geomorfología de La Región Centro Sur de La Provincia de San Juan, Argentina.” In Revista Simposio de Teledetección. X Congreso Geológico Argentino.

WANG, L., G. ZHANG, L. ZHU, & H. WANG. 2017. “Biocrust Wetting Induced Change in Soil Surface Roughness as Influenced by Biocrust Type, Coverage and Wetting Patterns.” Geoderma. 306 (June): 1–9. https://doi.org/10.1016/j.geoderma.2017.06.032.

WANG, Y., Y. ZHAO, C. YAO, & P. ZHANG.2014. “Surface Roughness Characteristics of Biological Soil Crusts and Its Influencing Factors in the Hilly Loess Plateau Region, China.” YingyongShengtaiXuebao.25 (3): 647–56.

WILLIAMS, A., B. BUCK, & M. BEYENE. 2012. “Biological Soil Crusts in the Mojave Desert, USA: Micromorphology and Pedogenesis.” Soil Sci. Soc. Am. J. 76 (5): 1685. https://doi.org/10.2136/sssaj2012.0021.

ZAADY, E., E.A. BEN-DAVID, Y. SHER, R. TZIRKIN, & A. NEJIDAT. 2010. Inferring biological soil crust successional stage using combined PLFA, DGGE, physical and biophysiological analyses. Soil Biology and Biochemistry, 42(5), 842-849

ZHENG, Z., S. HE, & F. WU. 2014. “Changes of Soil Surface Roughness under Water Erosion Process.” Hydrol.Proces. 28 (12): 3919–29. https://doi.org/10.1002/hyp.9939.

Published

2019-11-27

Issue

Section

Original Articles

How to Cite

“Microtopographic Characterization and Influence of Biological Soil Crusts on the Roughness of the Soil in the Center-West of Argentina”. 2019. Boletín De La Sociedad Argentina De Botánica (Journal of the Argentine Botanical Society 54 (4): 533-51. https://doi.org/10.31055/1851.2372.v54.n4.24163.

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