Digital Phytoindication of Soil Salinity in Dry Steppes (Republic of Kalmykia)

Digital Phytoindication of Soil Salinity in Dry Steppes (Republic of Kalmykia)

Soil and geobotanical studies were carried out in a landscape district within the Northern Sarpa lowland of the Caspian Depression in a zone of light-chestnut soil. The collected data made it possible to assess the variation of soil-salinity values typical for dry-steppe plant species and communitie...

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Bibliographic Details
Published in:Arid ecosystems Vol. 11; no. 2; pp. 173 - 185
Main Authors: Prokopyeva, K. O., Konyushkova, M. V., Novikova, N. M., Sobolev, I. V.
Format: Journal Article
Language:English
Published: Moscow Pleiades Publishing 01-04-2021
Springer Nature B.V
Subjects:
Biomedical and Life Sciences
Boreholes
Depth
Ecology
Festuca valesiaca
Flowers & plants
Grasses
Halophytes
Herbivores
Identification
Kochia prostrata
Life Sciences
Plant communities
Plant populations
Plant species
Regression analysis
Saline soils
Salinity
Salinity effects
Soil
Soil salinity
Soil testing
Species
Steppes
Systematic Study of Arid Territories
Tanacetum
significance
CART and Random Forest algorithms
communication models
indication accuracy
plant species and communities
indicators of salinization depth and degree
validity
machine learning
soil salinization
phytoindication
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Summary:Soil and geobotanical studies were carried out in a landscape district within the Northern Sarpa lowland of the Caspian Depression in a zone of light-chestnut soil. The collected data made it possible to assess the variation of soil-salinity values typical for dry-steppe plant species and communities in the Republic of Kalmykia and to produce digital models for a geobotanical indication of soil salinity. Geobotanical plots, soil test pits, and boreholes up to 2 m deep were established along a 64-m transect at 1 m intervals. The pNa salinity index was measured in aqueous suspensions of soil samples (1 : 5). As a result, it became possible to determine the salinity at depths of 0–30, 0–50, and 0–100 cm for 12 plant species and 7 plant communities registered on the transect and to distinguish three plant groups based on their tolerance to soil salinity. The first group includes species confined to nonsaline soils (salt concentrations vary within a narrow range). Plants belonging to the second group tolerate a broad range of salinity values and prefer nonsaline soils. The third group consists of salt loving species (halophytes) confined to saline and highly saline soils. Of the seven plant communities registered on the transect, two occur on nonsaline (down to a depth of 2 m) soils ( Stipa lessingiana + Festuca valesiaca + Artemisia lerchiana and Stipa lessingiana + Festuca valesiaca + Tanacetum achilleifolium ); two others tend to occur in soils that are not saline to a depth of 50 cm ( Festuca valesiaca + Artemisia lerchiana + Tanacetum achilleifolium and Artemisia lerchiana + Tanacetum achilleifolium + Artemisia pauciflora ); and three communities occur only on soils that are saline from a depth of  25–50 cm ( Kochia prostrata + Artemisia pauciflora , Artemisia pauciflora , and Poa bulbosa + Anabasis aphylla ). The Classification and Regression Tree (CART) method makes it possible to predict the soil salinity based on the occurrence of plant species identified as predictors. The prediction accuracy is 80% for the 0- to 30-cm layer, 81% for the 0- to 50-cm layer, and 64% for the 0- to 100-cm layer. The following plants have been identified as important (rank > 60) predictors: Kochia prostrata , Tanacetum achilleifolium , Artemisia austriaca , and Festuca valesiaca . Other species feature low prediction importance (validity) values and therefore cannot be used as predictors.
ISSN:2079-0961
2079-0988
DOI:10.1134/S207909612102013X