The production of biomass is one of

The production of biomass is one of the most basic and encompassing ecosystem services provided by wetlands. This reflects the creation of habitat for rare species as well as supporting recreational birding and economic gain (Okruszko et al., 2011). Biomass can also be a reflection of the system's ability to remove excessive nutrients such as nitrogen and phosphorous from the water. This can be seen in the presence of high-biomass accumulators such as Typha, which require large amounts of these nutrients and are often used in wetlands constructed specifically for nutrient removal ( Tang et al., 2011). In our study, we observed M. ringens and J. effusus accumulated large amounts of biomass ( Table 2) without the excessive colonization often observed with Typha, thus preserving plant community diversity. The decrease in biomass production at the highest PD (i.e., PD4), observed in this study ( Table 1), is somewhat the opposite to the findings of other studies ( Loreau, 2000; Tilman et al., 2001; Tilman et al., 1997 and Schultz et al., 2012) where a positive relationship between plant diversity and productivity was found. One possible explanation for this change in biomass production may be that the taller species, M. ringens and J. effusus, shaded out the competing E. obtusa and C. vulpinoidea ( Fig. 1). It was demonstrated in Ervin and Wetzel (2002) that shading produced by J. effusus limited richness and biomass of surrounding species. In addition, Juncus effuses, being a perennial species, exhibits year-round growth ( Wetzel and Howe, 1999). This gives the species ample time to accumulate biomass, potentially limiting nutrients available for the other species between growing seasons. Because our mesocosms did not receive any additional nutrient input from fertilizer or local runoff, additional studies should be performed to determine if nutrient limitation impacted vegetation development.

Schultz et al. (2012) suggested that reeds might inhibit the growth of tussocks, explaining the limited AGB accumulation of C. vulpinoidea observed in our mesocosms. Lawrence and Zedler (2013) reported that the majority of biomass C in Carex stricta was allocated to the root system during the formation of tussocks. Based on AGB alone, C. vulpinoidea exhibited limited productivity in comparison to other species. The inclusion of belowground biomass would likely have presented a more complete view of overall biomass allocation in all planted species. E. obtusa, being a ruderal species, grows early and spreads quickly. This gives E. obtusa an advantage when initially populating a created wetland. Our study suggests, however, that after the first growing season this advantage no longer exists and the growth of E. obtusa is inhibited by the neighboring species, yielding limited biomass (unpublished data).