Abstract
Long-term or cumulative diversity is the biodiversity that accumulates at a site over many generations of community members. Cumulative diversity is likely important to the intrinsic and functional value of ecosystems given the legacies left behind by many species. While its components—average short-term diversity (alpha) and temporal turnover (beta)—have been extensively studied, cumulative diversity itself has not. We therefore examined the environmental and community drivers of cumulative diversity with a novel hierarchical diversity partition. This partition breaks cumulative diversity into short-term, turnover, richness, and evenness components. We applied this framework to 49 tropical rock pool communities, censused over tens to hundreds of organism generations. Results uncovered two environmental regimes that differentially impacted the richness and evenness components of cumulative diversity: Occasional drying events mainly limited richness and reset communities, while less severe physicochemical variations reduced the evenness of communities. These causal pathways amount to differential controls on cumulative diversity; controls that can oppose each other to buffer diversity against change as well as create unexpected trade-offs for managers. We conclude that maintaining diversity at longer timescales requires new analytical tools and an expanded view that can account for its complexity.
Highlights
Managing the variety of life on Earth is complicated by the fact that diversity patterns change with the timescale of observation
From [26], we noted that gamma measures like γS and γE can each be partitioned into alpha and beta components of the forms: γS = αS βS and γE = αE βE
Percentage of cyclic species was positively associated with alpha richness (r = 0.63, p < 0.001), while more new additions and transient species led to higher compositional turnover or βS (r = 0.51, p < 0.001; r = 0.49, p < 0.001)
Summary
Managing the variety of life on Earth is complicated by the fact that diversity patterns change with the timescale of observation. Most diversity investigations apply a fine temporal grain, censusing species over short sampling periods, such as within a generation or two of the average community member. It is important to note that even though short-term diversity can be tracked over long periods of time (e.g., tens of thousands of years [3]), the fine grain of analysis reveals only trends in the diversity of contemporaneous species. It does not uncover the full biological diversity that influences a site over longer timespans
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