Your search keyword '"Benjamin Rosenbaum"' showing total 2 results

1. A size-constrained feeding-niche model distinguishes predation patterns between aquatic and terrestrial food webs

Author

Jingyi Li, Mingyu Luo, Shaopeng Wang, Benoit Gauzens, Myriam R. Hirt, Benjamin Rosenbaum, and Ulrich Brose

Subjects

Food Chain, Predatory Behavior, Animals, Body Size, Models, Theoretical, Ecology, Evolution, Behavior and Systematics

Abstract

Understanding the formation of feeding links provides insights into processes underlying food webs. Generally, predators feed on prey within a certain body-size range, but a systematic quantification of such feeding niches is lacking. We developed a size-constrained feeding-niche (SCFN) model and parameterized it with information on both realized and non-realized feeding links in 72 aquatic and 65 terrestrial food webs. Our analyses revealed profound differences in feeding niches between aquatic and terrestrial predators and variation along a temperature gradient. Specifically, the predator-prey body-size ratio and the range in prey sizes increase with the size of aquatic predators, whereas they are nearly constant across gradients in terrestrial predator size. Overall, our SCFN model well reproduces the feeding relationships and predation architecture across 137 natural food webs (including 3878 species and 136,839 realized links). Our results illuminate the organisation of natural food webs and enables novel trait-based and environment-explicit modelling approaches.

Published

2022

2. Biotic filtering by species' interactions constrains food-web variability across spatial and abiotic gradients

Author

Barbara Bauer, Emilio Berti, Remo Ryser, Benoit Gauzens, Myriam R. Hirt, Benjamin Rosenbaum, Christoph Digel, David Ott, Stefan Scheu, and Ulrich Brose

Subjects

Soil, Food Chain, Biodiversity, Forests, Ecology, Evolution, Behavior and Systematics, Ecosystem

Abstract

Despite intensive research on species dissimilarity patterns across communities (i.e. β-diversity), we still know little about their implications for variation in food-web structures. Our analyses of 50 lake and 48 forest soil communities show that, while species dissimilarity depends on environmental and spatial gradients, these effects are only weakly propagated to the networks. Moreover, our results show that species and food-web dissimilarities are consistently correlated, but that much of the variation in food-web structure across spatial, environmental, and species gradients remains unexplained. Novel food-web assembly models demonstrate the importance of biotic filtering during community assembly by (1) the availability of resources and (2) limiting similarity in species' interactions to avoid strong niche overlap and thus competitive exclusion. This reveals a strong signature of biotic filtering processes during local community assembly, which constrains the variability in structural food-web patterns across local communities despite substantial turnover in species composition.

Published

2021