W. Stanley Harpole, Lauren L. Sullivan, Eric M. Lind, Jennifer Firn, Peter B. Adler, Elizabeth T. Borer, Jonathan Chase, Philip A. Fay, Yann Hautier, Helmut Hillebrand, Andrew S. MacDougall, Eric W. Seabloom, Jonathan D. Bakker, Marc W. Cadotte, Enrique J. Chaneton, Chengjin J. Chu, Nicole Hagenah, Kevin Kirkman, Kimberly J. La Pierre, Joslin L. Moore, John W. Morgan, Suzanne M. Prober, Anita C. Risch, Martin Schuetz, Carly J. Stevens
1. The paradigmatic hypothesis for the effect of fertilisation on plant diversity represents a one‐dimensional trade‐off for plants competing for below‐ground nutrients (generically) and above‐ground light: fertilisation reduces competition for nutrients while increasing biomass and thereby shifts competition for depleted available light.
2. The essential problem of this simple paradigm is that it misses both the multivariate and mechanistic nature of the factors that determine biodiversity as well as their causal relationships.
3. We agree that light limitation, as DeMalach and Kadmon argue, can indeed be an important factor associated with diversity loss, and we presented it as an integral part of our tests of the niche dimension hypothesis.
4. We disagree with DeMalach and Kadmon that light is the ‘main’ factor explaining diversity, because this misrepresents the causal structure represented in the design of our experiment in which multiple nutrient addition was the ultimate causal driver of a suite of correlated responses that included diversity and light, and especially live and dead biomass, which are the factors that control light depletion.
5. Our findings highlight that multiple nutrient limitations can structure plant diversity and composition independently of changes in light and biomass. For example, approximately one‐third of our sites showed no significant increase in biomass with greater number of added nutrients yet still lost diversity when nutrients were added.
6. The important message is that while light limitation can be an important contributor to diversity loss, it is not a necessary mechanism.
2. The essential problem of this simple paradigm is that it misses both the multivariate and mechanistic nature of the factors that determine biodiversity as well as their causal relationships.
3. We agree that light limitation, as DeMalach and Kadmon argue, can indeed be an important factor associated with diversity loss, and we presented it as an integral part of our tests of the niche dimension hypothesis.
4. We disagree with DeMalach and Kadmon that light is the ‘main’ factor explaining diversity, because this misrepresents the causal structure represented in the design of our experiment in which multiple nutrient addition was the ultimate causal driver of a suite of correlated responses that included diversity and light, and especially live and dead biomass, which are the factors that control light depletion.
5. Our findings highlight that multiple nutrient limitations can structure plant diversity and composition independently of changes in light and biomass. For example, approximately one‐third of our sites showed no significant increase in biomass with greater number of added nutrients yet still lost diversity when nutrients were added.
6. The important message is that while light limitation can be an important contributor to diversity loss, it is not a necessary mechanism.