Your search keyword '"Oñatibia, Gastón R."' showing total 2 results

1. Richness, not evenness, varies across water availability gradients in grassy biomes on five continents.

Author

Smith, Melinda D., Koerner, Sally E., Avolio, Meghan L., Komatsu, Kimberly J., Eby, Stephanie, Forrestel, Elisabeth J., Collins, Scott L., Wilcox, Kevin R., Ahumada, Rodrigo, Morgan, John W., Oliva, Gabriel, Oñatibia, Gastón R., Overbeck, Gerhard E., Peter, Guadalupe, Quiroga, Emiliano, Sankaran, Mahesh, Wu, Jianshuang, Yahdjian, Laura, and Yu, Qiang

Subjects

WATER supply, BIOMES, CONTINENTS, SPECIES diversity, CLIMATE change

Abstract

We sought to understand the role that water availability (expressed as an aridity index) plays in determining regional and global patterns of richness and evenness, and in turn how these water availability–diversity relationships may result in different richness–evenness relationships at regional and global scales. We examined relationships between water availability, richness and evenness for eight grassy biomes spanning broad water availability gradients on five continents. Our study found that relationships between richness and water availability switched from positive for drier (South Africa, Tibet and USA) vs. negative for wetter (India) biomes, though were not significant for the remaining biomes. In contrast, only the India biome showed a significant relationship between water availability and evenness, which was negative. Globally, the richness–water availability relationship was hump-shaped, however, not significant for evenness. At the regional scale, a positive richness–evenness relationship was found for grassy biomes in India and Inner Mongolia, China. In contrast, this relationship was weakly concave-up globally. These results suggest that different, independent factors are determining patterns of species richness and evenness in grassy biomes, resulting in differing richness–evenness relationships at regional and global scales. As a consequence, richness and evenness may respond very differently across spatial gradients to anthropogenic changes, such as climate change. [ABSTRACT FROM AUTHOR]

Published

2022

2. Long-term impact of domestic ungulates versus the local controls of the litter decomposition process in arid steppes.

Author

Piazza, Maria-Victoria, Oñatibia, Gastón R., Aguiar, Martín R., and Chaneton, Enrique J.

Subjects

*STEPPES, *UNGULATES, *ENVIRONMENTAL soil science, *ARID soils, *GRASSLAND soils, *GRAZING, *ECOSYSTEMS

Abstract

Aims: Soil processes in arid ecosystems are strongly controlled by resource scarcity. Grazing intensification can induce changes in ecosystem processes through multiple pathways, adding new constraints to those of local conditions. We focus on grazing-induced changes in litter traits and soil environment that may affect litter decomposition and N dynamics in temperate grass-shrub steppes. Methods: We performed three litterbag decomposition experiments to evaluate: i) the effect of litter traits in a common garden (ex situ), ii) the effect of soil environment using a foreign common litter substrate (in situ), and iii) the interactive effects of litter traits and soil environment (grazed vs. exclosure communities, reciprocal transplants in situ). Field experiments were replicated in three blocks with paired plots under a long-term exclosure (> 25 years) and under year-round sheep grazing. Local litter included mixtures of species of grasses and shrubs, separately. Results: Grazing exclusion did not alter litter decomposition rates, either through changes in litter traits or in soil environment. Nevertheless, N released during grass litter decomposition was 286% higher in exclosures than in grazing communities. The difference was associated to changes in litter C:N ratio. The effects were maintained when results were integrated to the entire litter community. Conclusion: Our study suggests that litter decomposition rates in arid steppes are strongly controlled by local drivers. Ungulate grazing does not have an important influence on litter mass loss, but it can exert a strong control on N flux during decomposition, by changing grass litter traits. [ABSTRACT FROM AUTHOR]

Published

2021