Journal
ECOSYSTEMS
Volume 24, Issue 4, Pages 825-839Publisher
SPRINGER
DOI: 10.1007/s10021-020-00552-1
Keywords
Light; Efficiency; Primary production; Benthic; Dissolved color; Stream; River; Water column; Attenuation
Categories
Funding
- St. Johns River Water Management District [27789]
- National Science Foundation [DEB 1442140]
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This study found that quantifying benthic light rigorously has a significant impact on GPP predictions and can constrain variations in LUE across different sites. By considering mean-light conditions, the ecosystem's light-capture ability can be quantified more effectively, which improves predictions of GPP.
Light-use efficiency (LUE) describes conversion of incident light into gross primary production (GPP), combining the inherent photosynthetic efficiency of chloroplasts with light-capture ability of the autotrophic community. In lotic ecosystems, LUE is poorly constrained, in part because most studies neglect water-column attenuation. We hypothesized that rigorous quantification of benthic light would (1) improve GPP predictions and (2) constrain cross-site variation in LUE. We used a field-validated light model to successively attenuate open-sky irradiance through the riparian canopy and water column to estimate benthic light at 11 sites spanning discharge and dissolved-color gradients where we simultaneously calculated daily GPP. Our results indicate substantial water-column attenuation (up to 96% of stream-surface light), implying significant underestimation of LUE using stream-surface light alone. Benthic light dramatically improved GPP predictions, especially after considering mean-light conditions, which we suggest enumerates ecosystem light-capture ability due to biomass density. The model including mean-light effects explained 78% of GPP variation across sites and yielded a LUE identical to terrestrial ecosystems (1.9%). Interactions between daily and mean-light only slightly improved model fit (R-2 = 0.80), implying higher LUE at sites with higher mean light, but notably reduced LUE variation across sites compared with individual site analyses. This suggests that better representation of benthic light regimes leads to LUE convergence. Our study supports use of a global river LUE to translate large-scale predictions of stream light regimes into expected GPP, from which disturbance and nutrient limitation effects can then be discerned.
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