Shifts of community composition and population density substantially affect ecosystem function despite invariant richness JW Spaak, JM Baert, DJ Baird, N Eisenhauer, L Maltby, F Pomati, ... Ecology Letters 20 (10), 1315-1324, 2017 | 93 | 2017 |
Intuitive and broadly applicable definitions of niche and fitness differences JW Spaak, F De Laender Ecology Letters 23 (7), 1117-1128, 2020 | 69 | 2020 |
Mapping species niche and fitness differences for communities with multiple interaction types JW Spaak, O Godoy, F De Laender Oikos 130 (12), 2065-2077, 2021 | 30 | 2021 |
Reinterpreting the relationship between number of species and number of links connects community structure and stability C Carpentier, G Barabás, JW Spaak, F De Laender Nature Ecology & Evolution 5 (8), 1102-1109, 2021 | 22 | 2021 |
Species richness increases fitness differences, but does not affect niche differences JW Spaak, C Carpentier, F De Laender Ecology Letters 24 (12), 2611-2623, 2021 | 19* | 2021 |
Effects of pigment richness and size variation on coexistence, richness and function in light‐limited phytoplankton JW Spaak, F De Laender Journal of Ecology 109 (6), 2385-2394, 2021 | 18 | 2021 |
Chemical mixtures and multiple stressors: same but different? RB Schäfer, M Jackson, N Juvigny‐Khenafou, SE Osakpolor, L Posthuma, ... Environmental Toxicology and Chemistry 42 (9), 1915-1936, 2023 | 16 | 2023 |
Niche differences, not fitness differences, explain predicted coexistence across ecological groups L Buche, JW Spaak, J Jarillo, F De Laender Journal of Ecology 110 (11), 2785-2796, 2022 | 16 | 2022 |
Different measures of niche and fitness differences tell different tales JW Spaak, PJ Ke, AD Letten, F De Laender Oikos 2023 (4), e09573, 2023 | 13 | 2023 |
The effect of non-linear competitive interactions on quantifying niche and fitness differences JW Spaak, R Millet, PJ Ke, AD Letten, F De Laender Theoretical Ecology 16 (2), 161-170, 2023 | 8 | 2023 |
Mechanistic models of trophic interactions: opportunities for species richness and challenges for modern coexistence theory JW Spaak, PB Adler, SP Ellner The American Naturalist 202 (1), E1-E16, 2023 | 6 | 2023 |
Modeling phytoplankton-zooplankton interactions: opportunities for species richness and challenges for modern coexistence theory JW Spaak, PB Adler, SP Ellner bioRxiv, 2022.03. 24.485680, 2022 | 6 | 2022 |
Building modern coexistence theory from the ground up: the role of community assembly JW Spaak, SJ Schreiber Ecology Letters 26 (11), 1840-1861, 2023 | 4 | 2023 |
cyanoFilter: An r package to identify phytoplankton populations from flow cytometry data using cell pigmentation and granularity OD Olusoji, JW Spaak, M Holmes, T Neyens, M Aerts, F De Laender Ecological Modelling 460, 109743, 2021 | 4 | 2021 |
Stressor richness intensifies productivity loss but mitigates biodiversity loss M Holmes, JW Spaak, F De Laender Ecology and Evolution 11 (21), 14977-14987, 2021 | 4 | 2021 |
Food web uncertainties influence predictions of climate change effects on soil carbon sequestration in heathlands W Reyns, F Rineau, JW Spaak, O Franken, MP Berg, F Van Der Plas, ... Microbial ecology 79 (3), 686-693, 2020 | 4 | 2020 |
Continuous assembly required: Perpetual species turnover in two‐trophic‐level ecosystems JW Spaak, PB Adler, SP Ellner Ecosphere 14 (7), e4614, 2023 | 3 | 2023 |
Niche differences, not fitness differences, explain coexistence across ecological groups L Buche, JW Spaak, J Jarillo, F De Laender bioRxiv, 2021.11. 15.468654, 2021 | 3 | 2021 |
Towards mechanistic integration of the causes and consequences of biodiversity S Wang, P Hong, PB Adler, E Allan, Y Hautier, B Schmid, JW Spaak, ... Trends in ecology & evolution, 2024 | 2 | 2024 |
Multitrophic assembly: a perspective from modern coexistence theory C Song, JW Spaak bioRxiv, 2023.03. 20.533409, 2023 | 2 | 2023 |