Primary Succession and Forest Development on Coastal Lake Michigan Sand Dunes

Lichter, John

doi:10.2307/2657151

Cited by 98 publications

(134 citation statements)

References 86 publications

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“…It is not obvious whether this is a cause or an effect of tiller density. Soil organic matter increases with time in primary successional systems due to the facilitative effects of early plant colonizers (e.g., Chapin et al 1994, Lichter 1998, so it is possible that soil organic matter responds directly to A. breviligu- Hacker et al (2012) found that sand supply rates (cm sand deposition per month) differed among sites and were better predictors of tiller densities than were local climate factors. Ammophila breviligulata is adapted to the dune environment and actually dependent on moving sand and burial to maintain vigorous populations (Maun and Lapierre 1984).…”

Section: Discussionmentioning

confidence: 99%

Biotic and abiotic predictors of ecosystem engineering traits of the dune building grass, Ammophila breviligulata

Emery

Rudgers

2014

Ecosphere

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Citation: Emery, S. M., and J. A. Rudgers. 2014. Biotic and abiotic predictors of ecosystem engineering traits of the dune building grass, Ammophila breviligulata. Ecosphere 5(7):87. http://dx.doi.org/10.1890/ES13-00331.1Abstract. Ecosystem engineers are species that fundamentally influence their community and ecosystem by creating or altering the physical structure of habitats. However, the function of ecosystem engineers is variable and can depend on abiotic and biotic factors. In this study, we characterized the ecosystem engineering traits of plant size and tiller density for the dune grass, Ammophila breviligulata, in 37 sites across a broad geographic gradient in the western Great Lakes region. We also measured 20 biotic and abiotic factors related to climate, soil chemistry, and fungal symbionts associated with these survey sites and assessed their relationships with A. breviligulata population traits and dune plant species richness. Climate factors, especially temperature and precipitation, were positively associated with A. breviligulata tiller size, while soil organic matter was the only factor associated with tiller density. Several factors, including temperature, soil nitrogen, and mycorrhizal colonization, were associated with plant richness across our sites. Our results suggest that climate can influence at least some ecosystem engineering traits (i.e., plant size) of an important dune building species, although general conclusions from our work indicate that the population trait tied most closely with dune building ability-population density-is not strongly influenced by climate at the regional scale. This offers insight for conservationists interested in preserving intact dune ecosystems in a changing climate, but further work is needed to reconcile conflicting lab and field studies.

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Section: Discussionmentioning

confidence: 99%

Biotic and abiotic predictors of ecosystem engineering traits of the dune building grass, Ammophila breviligulata

Emery

Rudgers

2014

Ecosphere

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“…Dunes support high ecological diversity and contain many endemic and endangered species due to their geomorphological and environmental heterogeneity (Powell 1981;Lichter 1998;Van der Maarel 2003). However, they are fragile ecosystems and suffer from many kinds of natural and anthropogenic disturbance including hurricanes, invasive species, global sea-level rise, urbanization, and improper management (Feagin et al 2005;Grunewald 2006;El Banna and Mahmoud 2008;Bonte and Maes 2008;Claudino-Sales et al 2008;Marchante et al 2008;Jackson and Cooper 2011;Provoost et al 2011).…”

Section: Introductionmentioning

confidence: 99%

Ant community structure and response to disturbances on coastal dunes of Gulf of Mexico

et al. 2014

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Coastal dunes are complex and fragile ecosystems. The decrease in environmental stressors from sea to inland creates zonation patterns of habitats, which support high biodiversity. Although coastal dunes have been examined in primary succession studies for more than 100 years, invertebrates have received much less attention than other taxa. In this study, we examined ant community composition and its relationship with vegetation structure on dunes, and used ants as indicators to reveal the influence of anthropogenic disturbances on these habitats. Quadrat sampling, hand collecting, and beating plants were used to sample ants on coastal dunes fringing the northern Gulf of Mexico. Ants representing 44 species were found, with diversity and number of functional groups increasing from foredunes to backdunes. Bush areas of the backdunes supported a unique ant community. Ant diversity was correlated with plant richness, stem number, and plant cover, but the correlation was not consistent among habitats. Ant diversity was lower in degraded, young-planted, and re-built but not in old-planted sites. In addition, different types of disturbance changed the ant community and functional groups in different ways. Our study emphasizes the importance of protecting the whole dune system, especially the backdunes, which support high diversity but are often completely destroyed by urban development. Data from this research provides a benchmark to examine trajectories of coastal dune ecosystem degradation or recovery when exposed to natural or anthropogenic disturbances.

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“…Because the sites are separated in space and studied at the same time, with changes over time inferred, this technique is called a "space-for-time substitution". Chronosequence approaches have provided valuable insight into patterns of forest succession and soil development (Cowles 1899;Billings 1938;Dickson and Crocker 1953;Crocker and Major 1955;Crews and others 1995;Lichter 1998), but they can be subject to error in the space-for-time substitution if sites differ in respects other than their age. To avoid this problem, researchers try to minimize sources of variation other than time by selecting sites that are similar in other respects.…”

Section: Introductionmentioning

confidence: 99%

Soil Carbon Dynamics after Forest Harvest: An Ecosystem Paradigm Reconsidered

2003

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In one of the most influential studies in the recent history of forest ecology, W. W. Covington (1981) described a pattern in organic matter storage in the forest floors of northern hardwood stands as a function of date of harvest. We review the history of the use and misuse of Covington's curve, describe the studies that tested and failed to support early interpretations of the curve, and provide some alternate interpretations. The curve suggested that forest floor organic matter declines by 50% within 20 years after harvest, and this decline was attributed to accelerated decomposition and changes in litter inputs after harvest. Subsequent studies showed that decomposition rates of surface litter generally decrease after clear-cutting, but accelerated decomposition remains possible in the Oe and Oa horizons. Changes in litter inputs are still difficult to evaluate, because the rate at which woody debris enters the forest floor is unknown. Although Covington attempted to minimize variation due to mechanical disturbance during logging, a reasonable alternative explanation for low organic matter in the forest floor of young stands is that surface material is mixed into mineral soil during harvesting operations. The pattern of forest floor organic matter in stands of different ages may be partly due to changes over time in logging technology and the intensity of biomass removal, in addition to successional effects. It is important to distinguish between mechanisms that release carbon to the atmosphere and those that transfer it to the mineral soil before making inferences about nutrient cycling and carbon sequestration.

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Primary Succession and Forest Development on Coastal Lake Michigan Sand Dunes

Cited by 98 publications

References 86 publications

Biotic and abiotic predictors of ecosystem engineering traits of the dune building grass, Ammophila breviligulata

Biotic and abiotic predictors of ecosystem engineering traits of the dune building grass, Ammophila breviligulata

Ant community structure and response to disturbances on coastal dunes of Gulf of Mexico

Soil Carbon Dynamics after Forest Harvest: An Ecosystem Paradigm Reconsidered

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