Biomass harvest of invasive <i>Typha</i> promotes plant diversity in a Great Lakes coastal wetland

Lishawa, Shane C.; Lawrence, Beth A.; Albert, Dennis A.; Tuchman, Nancy C.

doi:10.1111/rec.12167

Cited by 46 publications

(57 citation statements)

References 40 publications

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“…Although harvesting biomass increased light penetration to the soil surface in the first growing season, we did not observe enhanced native plant density or biomass relative to controls, possibly indicating depauperate seed banks within the mesocosm soils. In a northern Michigan field experiment however, harvest of aboveground Typha biomass increased native plant diversity and richness for at least 2 years relative to unmanipulated controls (Lishawa et al 2015), and resulted in greater plant richness than mowing (Lawrence et al unpublished data). Hall et al (2008) also observed greater plant richness and diversity with harvest of T. dominegensis in central Mexican wetlands compared with unmanipulated controls.…”

Section: Mechanical Harvest Of Typha Biomassmentioning

confidence: 97%

“…For example, assuming similar N and P content of leaf and litter biomass that we measured in the current study (%N = 0.9 %, %P = 0.2 %), a one-time harvest of Typha-invaded portions (16 ha) of Cheboygan Marsh in northern Michigan (USA) would remove approximately 4100 kg of N and 910 kg of P (assuming 2846 g dry biomass/m 2 ; Lishawa et al 2015), helping achieve pollutant load reduction goals of nutrient-impaired Lake Huron. Similarly, Boyd et al (2015) quantified biomass and leaf nutrient content of a Phragmites-invaded wetland in central Florida and estimated that biomass harvest would address *25 % of Lake Jesup's pollutant load reduction goal.…”

Section: Mechanical Harvest Of Typha Biomassmentioning

confidence: 99%

“…Leaf litter deposited on wetland surfaces during mowing should release nutrients as it decays, though nutrient uptake during plant regrowth after cutting may prevent elevated N and P concentrations. Harvesting (removing) cut biomass and accumulated Typha litter has several potential advantages including: decreasing litter accumulation which drives terrestrialization (Rooth et al 2003), increasing plant diversity (Farrer and Goldberg 2014;Hall et al 2008;Lishawa et al 2015;Osland et al 2011), and reducing N and P from wetlands by removing nutrient-rich biomass (Boyd 1970;Hansson and Fredriksson 2004;Hosoi et al 1998), thereby reducing the invasion-stimulating effects of increased nutrient availability (Larkin et al 2012b;Woo and Zedler 2002). Mechanical harvest of wetland plants is common in European wetlands, where biomass is used for compost, fodder, building materials, or as a bioenergy source (Hansson and Fredriksson 2004;Köbbing et al 2013), and Typha harvest has been implemented at large spatial scales near Lake Winnipeg to remove nutrients and provide a bioenergy source (Cicek et al 2006, R. Grosshans pers.…”

Section: Introductionmentioning

confidence: 99%

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Herbicide management of invasive cattail (Typha × glauca) increases porewater nutrient concentrations

Lawrence

Lishawa

Rodriguez

et al. 2015

Wetlands Ecol Manage

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Invasive wetland plants are the primary targets of wetland management to promote native communities and wildlife habitat, but little is known about how commonly implemented restoration techniques influence nutrient cycling. We tested how experimental mowing, herbicide application, and biomass harvest (i.e., removal of aboveground biomass) treatments of Typha-invaded mesocosms altered porewater nutrient (NO 3 -, NH 4 ? , PO 4 -3 ) concentration and supply rate, vegetation response, and light penetration to the soil surface. We found that while herbicide application eliminated the target species, it also reduced native plant density and biomass, as well as increased porewater nutrient concentration (PO 4 -3 , NO 3 -) and supply rates (N, P, K) up to a year after treatments were implemented. Because herbicide application promotes nutrient enrichment, it may increase the likelihood of reinvasion by problematic wetland invaders, as well as cause eutrophication and deleterious algal blooms in adjacent aquatic systems. Our data suggest that biomass harvest should be considered by managers aiming to reduce Typha abundance without eradicating native diversity, avoid nutrient leaching, as well as possibly utilizing biomass for bioenergy.

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Section: Mechanical Harvest Of Typha Biomassmentioning

confidence: 97%

Section: Mechanical Harvest Of Typha Biomassmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Herbicide management of invasive cattail (Typha × glauca) increases porewater nutrient concentrations

Lawrence

Lishawa

Rodriguez

et al. 2015

Wetlands Ecol Manage

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“…dominance (Mulhouse and Galatowitsch, 2003; Hall and Zedler, 2010) due to relatively short term seed viability (van der Valk et al, 1999) and high light requirements for germination (Kettenring et al, 2006). Further, Lishawa et al (2015) found that in a northern Great Lakes coastal wetland, Carex spp. diversity and abundance took 2 years following Typha biomass removal to increase from pre-treatment levels.…”

Section: Discussionmentioning

confidence: 99%

Mechanical Harvesting Effectively Controls Young Typha spp. Invasion and Unmanned Aerial Vehicle Data Enhances Post-treatment Monitoring

et al. 2017

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The ecological impacts of invasive plants increase dramatically with time since invasion. Targeting young populations for treatment is therefore an economically and ecologically effective management approach, especially when linked to post-treatment monitoring to evaluate the efficacy of management. However, collecting detailed field-based post-treatment data is prohibitively expensive, typically resulting in inadequate documentation of the ecological effects of invasive plant management. Alternative approaches, such as remote detection with unmanned aerial vehicles (UAV), provide an opportunity to advance the science and practice of restoration ecology. In this study, we sought to determine the plant community response to different mechanical removal treatments to a dominant invasive wetland macrophyte (Typha spp.) along an age-gradient within a Great Lakes coastal wetland. We assessed the post-treatment responses with both intensive field vegetation and UAV data. Prior to treatment, the oldest Typha stands had the lowest plant diversity, lowest native sedge (Carex spp.) cover, and the greatest Typha cover. Following treatment, plots that were mechanically harvested below the surface of the water differed from unharvested control and above-water harvested plots for several plant community measures, including lower Typha dominance, lower native plant cover, and greater floating and submerged aquatic species cover. Repeated-measures analysis revealed that above-water cutting increased plant diversity and aquatic species cover across all ages, and maintained native Carex spp. cover in the youngest portions of Typha stands. UAV data revealed significant post-treatment differences in normalized difference vegetation index (NDVI) scores, blue band reflectance, and vegetation height, and these remotely collected measures corresponded to field observations. Our findings suggest that both mechanically harvesting the above-water biomass of young Typha stands and harvesting older stands below-water will promote overall native community resilience, and increase the abundance of the floating and submerged aquatic plant guilds, which are the most vulnerable to invasions by large macrophytes. UAV's provided fast and spatially expansive data compared to field monitoring, and effectively measured plant community structural responses to different treatments. Study results suggest pairing UAV flights with targeted field data collection to maximize the quality of post-restoration vegetation monitoring.

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“…This effect was further illustrated by the response of Juncus nodosus and J. alpinoarticulatus, which were indicator species significantly associated with harvesting in wet meadow plots. In the emergent marsh, cutting biomass below standing water (all treatments) effectively reduced Typha abundance, likely by preventing aeration and causing rhizome mortality (Jordan & Whigham, 1988;Murkin & Ward, 1980 (Lishawa et al, 2015). are prolific in GL coastal wetland seed banks (Keddy & Reznicek, 1986), and these early seral species can become the dominant emergent plants following water-level reduction and mudflat exposure (Tuchman unpublished), but they quickly disappear from the emergent community with succession or Typha invasion (Larkin et al, 2012;Tuchman et al, 2009).…”

Section: Taxonomic and Phylogenetic Diversity Responses To Restoratmentioning

confidence: 99%

Invasive species removal increases species and phylogenetic diversity of wetland plant communities

Lishawa

Lawrence

Albert

et al. 2019

Ecology and Evolution

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Plant invasions result in biodiversity losses and altered ecological functions, though quantifying loss of multiple ecosystem functions presents a research challenge. Plant phylogenetic diversity correlates with a range of ecosystem functions and can be used as a proxy for ecosystem multifunctionality. Laurentian Great Lakes coastal wetlands are ideal systems for testing invasive species management effects because they support diverse biological communities, provide numerous ecosystem services, and are increasingly dominated by invasive macrophytes. Invasive cattails are among the most widespread and abundant of these taxa. We conducted a three‐year study in two Great Lakes wetlands, testing the effects of a gradient of cattail removal intensities (mowing, harvest, complete biomass removal) within two vegetation zones (emergent marsh and wet meadow) on plant taxonomic and phylogenetic diversity. To evaluate native plant recovery potential, we paired this with a seed bank emergence study that quantified diversity metrics in each zone under experimentally manipulated hydroperiods. Pretreatment, we found that wetland zones had distinct plant community composition. Wet meadow seed banks had greater taxonomic and phylogenetic diversity than emergent marsh seed banks, and high‐water treatments tended to inhibit diversity by reducing germination. Aboveground harvesting of cattails and their litter increased phylogenetic diversity and species richness in both zones, more than doubling richness compared to unmanipulated controls. In the wet meadow, harvesting shifted the community toward an early successional state, favoring seed bank germination from early seral species, whereas emergent marsh complete removal treatments shifted the community toward an aquatic condition, favoring floating‐leaved plants. Removing cattails and their litter increased taxonomic and phylogenetic diversity across water levels, a key environmental gradient, thereby potentially increasing the multifunctionality of these ecosystems. Killing invasive wetland macrophytes but leaving their biomass in situ does not address their underlying mechanism of dominance and is less effective than more intensive treatments that also remove their litter.

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Biomass harvest of invasive Typha promotes plant diversity in a Great Lakes coastal wetland

Cited by 46 publications

References 40 publications

Herbicide management of invasive cattail (Typha × glauca) increases porewater nutrient concentrations

Herbicide management of invasive cattail (Typha × glauca) increases porewater nutrient concentrations

Mechanical Harvesting Effectively Controls Young Typha spp. Invasion and Unmanned Aerial Vehicle Data Enhances Post-treatment Monitoring

Invasive species removal increases species and phylogenetic diversity of wetland plant communities

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