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Root vertical distributions of two <i>Artemisia</i> species and their relationships with soil resources in the Hunshandake desert, China

Xiuli Gao, Xiaoqiang Liu, Linna Ma, Renzhong Wang

2020Ecology and Evolution15 citationsDOIOpen Access PDF

Abstract

Abstract Plant root variations and their relations with soil moisture and nutrient supply have been well documented for many species, while effects of drought, combined with extreme poor soil nutrients, on plant roots remain unclear. Herein, we addressed root vertical distributions of two typical xerophyte semishrub species, Artemisia sphaerocephala and A. intramongolica , and their relations with soil moisture, total soil nitrogen and carbon contents in arid Hunshandake desert, China. The two species experienced similar light regimes and precipitation, but differed in soil moisture and soil nutrients. Root vertical distribution patterns (e.g., coarse root diameter, root depth and root biomass) differed considerable for the two species due to high heterogeneity of soil environments. Coarse and fine root biomasses for A. intramongolica , distributed in relatively moist fixed dunes, mainly focused on surface layers (94%); but those for A. sphaerocephala dropped gradually from the surface to 140 cm depth. Relations between root traits (e.g., diameter, root biomass) and soil moisture were positive for A. intramongolica , but those for A. sphaerocephala were negative. In general, the root traits for both species positively correlated with total soil nitrogen and carbon contents. These findings suggest that both soil moisture and poor soil nutrients were the limiting resources for growth and settlement of these two species.

Topics & Concepts

NutrientAgronomyEnvironmental scienceWater contentBiomass (ecology)AridMoisturePrecipitationSoil waterSoil horizonBotanyBiologySoil scienceEcologyChemistryGeologyGeographyGeotechnical engineeringMeteorologyOrganic chemistryPlant Water Relations and Carbon DynamicsTree Root and Stability StudiesPlant responses to water stress