Annual growth and productivity of kelp in the Stefansson Sound Boulder Patch, located along the Arctic coast of Alaska, is regulated almost entirely by PAR received during the summer open-water period. Increased water turbidity during summer, often in response to storm activity, has been linked to low levels of ambient PAR and measurable decreases in kelp elongation. However, the relationship between PAR and water transparency has not been quantified, which compromises efforts to assess the effects of changing climate and weather conditions on kelp production. During the 2001-2002 summer periods, the inherent optical properties (IOPs) of Stefansson Sound waters were measured in conjunction with total suspended sediments (TSS) concentrations, which differed significantly between the 2 years, for input into a radiative transfer equation (RTE). In both years, the highest TSS levels (24.2 and 18.5 mg AE L )1 in 2001 and 2002, respectively) occurred in nearshore areas and were coincident with increased beam attenuations (13.8 and 8.3 m )1 ). Lower TSS concentrations and attenuations were measured offshore. Data input to the RTE provided a TSS-concentration-specific attenuation coefficient that was used in a productivity model to estimate annual kelp productivities throughout the Boulder Patch based on modeled irradiance and averaged site-specific TSS concentrations. Production estimates varied across the Boulder Patch but were lower in 2001 (0.12-0.34 g C AE g dwt )1 AE year )1 , where dwt stands for dry weight) compared to 2002 (0.24-0.80 g C AE g dwt )1 AE year )1 ). Production in both years was greater in offshore locations with lower TSS loads. Results suggest that PAR availability during the summer is heavily influenced by TSS concentrations, and that changes in storm intensity and frequency, associated with current warming trends, may have significant effects on the primary production of these unique benthic algal communities.
Plants of Acomastylis rossii and Bistorta vivipara were treated in the field with artificial acid mists prepared with sulfuric acid, nitric acid, or mixtures of equal parts of these at pH 2.5, 3.5, or 4.5. Highly significant reductions in flower production in A. rossii were noted with sulfuric acid treatments at pH 2.5 and in bulblet production in B. vivipara with nitric acid at pH 2.5 and 3.5, with sulfuric acid at pH 3.5, and with nitric‐sulfuric acid mixtures at all pH's. These results apparently relate to the growth forms of the plants, which cause pooling of the acid solutions at their bases. Significant increases in flowering and in leaf number were noted for B. vivipara treated with sulfuric acid, possibly as a promotive effect of sulfate. No effects on vegetative growth were noted in A. rossii. The germinability of seeds (A. rossii) and bulblets (B. vivipara) also was not affected. Differential sensitivity of plant species to artificial acid mist implies that acid precipitation could cause a change in species composition of Colorado alpine plant communities.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.