Your search keyword '"Fried‐Petersen, Hannah B."' showing total 7 results

1. Parallels of quantum superposition in ecological models: from counterintuitive patterns to eco-evolutionary interpretations of cryptic species

Author

Angeler, David G. and Fried-Petersen, Hannah B.

Published

2024

2. Adaptive capacity in ecosystems

Author

Angeler, David G., primary, Fried-Petersen, Hannah B., additional, Allen, Craig R., additional, Garmestani, Ahjond, additional, Twidwell, Dirac, additional, Chuang, Wen-Ching, additional, Donovan, Victoria M., additional, Eason, Tarsha, additional, Roberts, Caleb P., additional, Sundstrom, Shana M., additional, and Wonkka, Carissa L., additional

Published

2019

3. Drivers of long-term invertebrate community stability in changing Swedish lakes

Author

Fried-Petersen, Hannah B., Araya-Ajoy, Yimen G., Futter, Martyn N., Angeler, David G., Fried-Petersen, Hannah B., Araya-Ajoy, Yimen G., Futter, Martyn N., and Angeler, David G.

Abstract

Research on ecosystem stability has had a strong focus on local systems. However, environmental change often occurs slowly at broad spatial scales, which requires regional-level assessments of long-term stability. In this study, we assess the stability of macroinvertebrate communities across 105 lakes in the Swedish “lakescape.” Using a hierarchical mixed-model approach, we first evaluate the environmental pressures affecting invertebrate communities in two ecoregions (north, south) using a 23 year time series (1995–2017) and then examine how a set of environmental and physical variables affect the stability of these communities. Results show that lake latitude, size, total phosphorus and alkalinity affect community composition in northern and southern lakes. We find that lake stability is affected by species richness and lake size in both ecoregions and alkalinity and total phosphorus in northern lakes. There is large heterogeneity in the patterns of community stability of individual lakes, but relationships between that stability and environmental drivers begin to emerge when the lakescape, composed of many discrete lakes, is the focal unit of study. The results of this study highlight that broad-scale comparisons in combination with long time series are essential to understand the effects of environmental change on the stability of lake communities in space and time.

Published

2020

4. Drivers of long‐term invertebrate community stability in changing Swedish lakes

Author

Fried‐Petersen, Hannah B., primary, Araya‐Ajoy, Yimen G., additional, Futter, Martyn N., additional, and Angeler, David G., additional

Published

2020

5. Long‐term population dynamics of dreissenid mussels (Dreissena polymorpha and D. rostriformis): a cross‐system analysis

Author

Strayer, David L., Adamovich, Boris V., Adrian, Rita, Aldridge, David C., Balogh, Csilla, Burlakova, Lyubov E., Fried‐Petersen, Hannah B., Tóth, László G., Hetherington, Amy L., Jones, Thomas S., Karatayev, Alexander Y., Madill, Jacqueline B., Makarevich, Oleg A., Marsden, J. Ellen, Martel, André L., Minchin, Dan, Nalepa, Thomas F., Noordhuis, Ruurd, Robinson, Timothy J., Rudstam, Lars G., Schwalb, Astrid N., Smith, David R., Steinman, Alan D., and Jeschke, Jonathan M.

Subjects

biological invasions, Dreissena, invasive species, long-term studies, population performance

Abstract

Dreissenid mussels (including the zebra mussel Dreissena polymorpha and the quagga mussel D. rostriformis) are among the world’s most notorious invasive species, with large and widespread ecological and economic effects. However, their long-term population dynamics are poorly known, even though these dynamics are critical to determining impacts and effective management. We gathered and analyzed 67 long-term (>10 yr) data sets on dreissenid populations from lakes and rivers across Europe and North America. We addressed five questions: (1) How do Dreissena populations change through time? (2) Specifically, do Dreissena populations decline substantially after an initial outbreak phase? (3) Do different measures of population performance (biomass or density of settled animals, veliger density, recruitment of young) follow the same patterns through time? (4) How do the numbers or biomass of zebra mussels or of both species combined change after the quagga mussel arrives? (5) How does body size change over time? We also considered whether current data on long-term dynamics of Dreissena populations are adequate for science and management. Individual Dreissena populations showed a wide range of temporal dynamics, but we could detect only two general patterns that applied across many populations: (1) Populations of both species increased rapidly in the first 1–2 yr after appearance, and (2) quagga mussels appeared later than zebra mussels and usually quickly caused large declines in zebra mussel populations. We found little evidence that combined Dreissena populations declined over the long term. Different measures of population performance were not congruent; the temporal dynamics of one life stage or population attribute cannot generally be accurately inferred from the dynamics of another. We found no consistent patterns in the long-term dynamics of body size. The long-term dynamics of Dreissena populations probably are driven by the ecological characteristics (e.g., predation, nutrient inputs, water temperature) and their temporal changes at individual sites rather than following a generalized time course that applies across many sites. Existing long-term data sets on dreissenid populations, although clearly valuable, are inadequate to meet research and management needs. Data sets could be improved by standardizing sampling designs and methods, routinely collecting more variables, and increasing support.

Published

2019

6. Chapter One - Adaptive capacity in ecosystems.

Author

Angeler, David G., Fried-Petersen, Hannah B., Allen, Craig R., Garmestani, Ahjond, Twidwell, Dirac, Wen-Ching Chuang, Donovan, Victoria M., Eason, Tarsha, Roberts, Caleb P., Sundstrom, Shana M., and Wonkka, Carissa L.

Subjects

*ECOLOGY periodicals, *ECOSYSTEMS, *ECOLOGICAL research, *GLOBAL environmental change

Abstract

Understanding the capacity of ecosystems to adapt and to cope (i.e. adaptive capacity) with change is crucial to their management. However, definitions of adaptive capacity are often unclear and confusing, making application of this concept difficult. In this paper, we revisit definitions of adaptive capacity and operationalize the concept. We define adaptive capacity as the latent potential of an ecosystem to alter resilience in response to change. We present testable hypotheses to evaluate complementary attributes of adaptive capacity that may help further clarify the components and relevance of the concept. We suggest how sampling, inference and modelling can reduce key uncertainties incrementally over time and increase learning about adaptive capacity. Improved quantitative assessments of adaptive capacity are needed because of the high uncertainty about global change and its potential effect on the capacity of ecosystems to adapt to social and ecological change. An improved understanding of adaptive capacity might ultimately allow for more efficient and targeted management. [ABSTRACT FROM AUTHOR]

Published

2019

7. A quantitative framework for assessing ecological resilience.

Author

Baho DL, Allen CR, Garmestani AS, Fried-Petersen HB, Renes SE, Gunderson LH, and Angeler DG

Abstract

Quantitative approaches to measure and assess resilience are needed to bridge gaps between science, policy and management. In this paper, we revisit definitions of resilience and suggest a quantitative framework for assessing ecological resilience sensu Holling (1973). Ecological resilience as an emergent ecosystem phenomenon can be decomposed into complementary attributes (scales, adaptive capacity, thresholds and alternative regimes) that embrace the complexity inherent to ecosystems. Quantifying these attributes simultaneously provides opportunities to move from the assessment of specific resilience within an ecosystem towards a broader measurement of its general resilience. We provide a framework, based on testable hypotheses, which allows assessment of complementary attributes of ecological resilience. By implementing the framework in adaptive approaches to management, inference and modeling, key uncertainties can be reduced incrementally over time and learning about the general resilience of dynamic ecosystems maximized. Such improvements are needed because uncertainty about global environmental change impacts and their effects on resilience is high. Improved resilience assessments will ultimately facilitate an optimized use of limited resources for management.

Published

2017