Your search keyword '"Fritz, Ken M."' showing total 9 results

1. Zero or not? Causes and consequences of zero‐flow stream gage readings

Author

Zimmer, Margaret A, Kaiser, Kendra E, Blaszczak, Joanna R, Zipper, Samuel C, Hammond, John C, Fritz, Ken M, Costigan, Katie H, Hosen, Jacob, Godsey, Sarah E, Allen, George H, Kampf, Stephanie, Burrows, Ryan M, Krabbenhoft, Corey A, Dodds, Walter, Hale, Rebecca, Olden, Julian D, Shanafield, Margaret, DelVecchia, Amanda G, Ward, Adam S, Mims, Meryl C, Datry, Thibault, Bogan, Michael T, Boersma, Kate S, Busch, Michelle H, Jones, C Nathan, Burgin, Amy J, and Allen, Daniel C

Subjects

aquatic network, non-perennial, stream gages, streamflow, zero flow

Abstract

Streamflow observations can be used to understand, predict, and contextualize hydrologic, ecological, and biogeochemical processes and conditions in streams. Stream gages are point measurements along rivers where streamflow is measured, and are often used to infer upstream watershed-scale processes. When stream gages read zero, this may indicate that the stream has fully dried; however, zero-flow readings can also be caused by a wide range of other factors. Our ability to identify whether or not a zero-flow gage reading indicates a dry fluvial system has far reaching environmental implications. Incorrect identification and interpretation by the data user can lead to hydrologic, ecological, and/or biogeochemical predictions from models and analyses. Here, we describe several causes of zero-flow gage readings: frozen surface water, flow reversals, instrument error, and natural or human-driven upstream source losses or bypass flow. For these examples, we discuss the implications of zero-flow interpretations. We also highlight additional methodss for determining flow presence, including direct observations, statistical methods, and hydrologic models, which can be applied to interpret causes of zero-flow gage readings and implications for reach- and watershed-scale dynamics. Such efforts are necessary to improve our ability to understand and predict surface flow activation, cessation, and connectivity across river networks. Developing this integrated understanding of the wide range of possible meanings of zero-flows will only attain greater importance in a more variable and changing hydrologic climate.

Published

2020

2. Identifying invertebrate indicators for streamflow duration assessments in forested headwater streams.

Author

Fritz, Ken M., Kashuba, Roxolana O., Pond, Gregory J., Christensen, Jay R., Alexander, Laurie C., Washington, Benjamin J., Johnson, Brent R., Walters, David M., Thoeny, William T., and Weaver, Paul C.

Subjects

*STREAMFLOW, *AQUATIC invertebrates, *INVERTEBRATES, *RANDOM forest algorithms, *ECOLOGICAL regions, *EPHEMERAL streams

Abstract

Streamflow-duration assessment methods (SDAMs) are rapid, indicator-based tools for classifying streamflow duration (e.g., intermittent vs perennial flow) at the reach scale. Indicators are easily assessed stream properties used as surrogates of flow duration, which is too resource intensive to measure directly for many reaches. Invertebrates are commonly used as SDAM indicators because many are not highly mobile, and different species have life stages that require flow for different durations and times of the year. The objectives of this study were to 1) identify invertebrate taxa that can be used as SDAM indicators to distinguish between stream reaches having intermittent and perennial flow, 2) to compare indicator strength across different taxonomic and numeric resolutions, and 3) to assess the relative importance of season and habitat type on the ability of invertebrates to predict streamflow-duration class. We used 2 methods, random forest models and indicator species analysis, to analyze aquatic and terrestrial invertebrate data (presence/absence, density, and biomass) at the family and genus levels from 370 samples collected from both erosional and depositional habitats during both wet and dry seasons. In total, 36 intermittent and 53 perennial reaches were sampled along 31 forested headwater streams in 4 level II ecoregions across the United States. Random forest models for family- and genus-level datasets had stream classification accuracy ranging from 88.9 to 93.2%, with slightly higher accuracy for density than for presence/absence and biomass datasets. Season (wet/dry) tended to be a stronger predictor of streamflow-duration class than habitat (erosional/depositional). Many taxa at the family (58.8%) and genus level (61.6%) were collected from both intermittent and perennial reaches, and most taxa that were exclusive to 1 streamflow-duration class were rarely collected. However, 23 family-level or higher taxa (20 aquatic and 3 terrestrial) and 44 aquatic genera were identified as potential indicators of streamflow-duration class for forested headwater streams. The utility of the potential indicators varied across level II ecoregions in part because of representation of intermittent and perennial reaches in the dataset but also because of variable ecological responses to drying among species. Aquatic invertebrates have been an important field indicator of perennial reaches in existing SDAMs, but our findings highlight how including aquatic and terrestrial invertebrates as indicators of intermittent reaches can further maximize the data collected for streamflow-duration classifications. [ABSTRACT FROM AUTHOR]

Published

2023

3. A global perspective on the functional responses of stream communities to flow intermittence.

Author

Crabot, Julie, Mondy, Cedric P., Usseglio‐Polatera, Philippe, Fritz, Ken M., Wood, Paul J., Greenwood, Michelle J., Bogan, Michael T., Meyer, Elisabeth I., and Datry, Thibault

Subjects

BIOTIC communities, STREAMFLOW, ECOLOGICAL integrity, ECOLOGICAL disturbances, ENVIRONMENTAL degradation, ECOSYSTEMS, BIODIVERSITY

Abstract

The current erosion of biodiversity is a major concern that threatens the ecological integrity of ecosystems and the ecosystem services they provide. Due to global change, an increasing proportion of river networks are drying and changes from perennial to non‐perennial flow regimes represent dramatic ecological shifts with potentially irreversible alterations of community and ecosystem dynamics. However, there is minimal understanding of how biological communities respond functionally to drying. Here, we highlight the taxonomic and functional responses of aquatic macroinvertebrate communities to flow intermittence across river networks from three continents, to test predictions from underlying trait‐based conceptual theory. We found a significant breakpoint in the relationship between taxonomic and functional richness, indicating higher functional redundancy at sites with flow intermittence higher than 28%. Multiple strands of evidence, including patterns of alpha and beta diversity and functional group membership, indicated that functional redundancy did not compensate for biodiversity loss associated with increasing intermittence, contrary to received wisdom. A specific set of functional trait modalities, including small body size, short life span and high fecundity, were selected with increasing flow intermittence. These results demonstrate the functional responses of river communities to drying and suggest that on‐going biodiversity reduction due to global change in drying river networks is threatening their functional integrity. These results indicate that such patterns might be common in these ecosystems, even where drying is considered a predictable disturbance. This highlights the need for the conservation of natural drying regimes of intermittent rivers to secure their ecological integrity. [ABSTRACT FROM AUTHOR]

Published

2021

4. River ecosystem conceptual models and non‐perennial rivers: A critical review.

Author

Allen, Daniel C., Datry, Thibault, Boersma, Kate S., Bogan, Michael T., Boulton, Andrew J., Bruno, Daniel, Busch, Michelle H., Costigan, Katie H., Dodds, Walter K., Fritz, Ken M., Godsey, Sarah E., Jones, Jeremy B., Kaletova, Tatiana, Kampf, Stephanie K., Mims, Meryl C., Neeson, Thomas M., Olden, Julian D., Pastor, Amandine V., Poff, N. LeRoy, and Ruddell, Benjamin L.

Subjects

EPHEMERAL streams, CONCEPTUAL models, RIVERS, WATER, ECOSYSTEMS, STREAMFLOW

Abstract

Conceptual models underpin river ecosystem research. However, current models focus on continuously flowing rivers and few explicitly address characteristics such as flow cessation and drying. The applicability of existing conceptual models to nonperennial rivers that cease to flow (intermittent rivers and ephemeral streams, IRES) has not been evaluated. We reviewed 18 models, finding that they collectively describe main drivers of biogeochemical and ecological patterns and processes longitudinally (upstream‐downstream), laterally (channel‐riparian‐floodplain), vertically (surface water‐groundwater), and temporally across local and landscape scales. However, perennial rivers are longitudinally continuous while IRES are longitudinally discontinuous. Whereas perennial rivers have bidirectional lateral connections between aquatic and terrestrial ecosystems, in IRES, this connection is unidirectional for much of the time, from terrestrial‐to‐aquatic only. Vertical connectivity between surface and subsurface water occurs bidirectionally and is temporally consistent in perennial rivers. However, in IRES, this exchange is temporally variable, and can become unidirectional during drying or rewetting phases. Finally, drying adds another dimension of flow variation to be considered across temporal and spatial scales in IRES, much as flooding is considered as a temporally and spatially dynamic process in perennial rivers. Here, we focus on ways in which existing models could be modified to accommodate drying as a fundamental process that can alter these patterns and processes across spatial and temporal dimensions in streams. This perspective is needed to support river science and management in our era of rapid global change, including increasing duration, frequency, and occurrence of drying. This article is categorized under:Water and Life > Nature of Freshwater EcosystemsWater and Life > Stresses and Pressures on EcosystemsScience of Water > Hydrological Processes [ABSTRACT FROM AUTHOR]

Published

2020

5. Zero or not? Causes and consequences of zero‐flow stream gage readings.

Author

Zimmer, Margaret A., Kaiser, Kendra E., Blaszczak, Joanna R., Zipper, Samuel C., Hammond, John C., Fritz, Ken M., Costigan, Katie H., Hosen, Jacob, Godsey, Sarah E., Allen, George H., Kampf, Stephanie, Burrows, Ryan M., Krabbenhoft, Corey A., Dodds, Walter, Hale, Rebecca, Olden, Julian D., Shanafield, Margaret, DelVecchia, Amanda G., Ward, Adam S., and Mims, Meryl C.

Subjects

ICE, GAGES, WATER, RIVERS, STREAMFLOW, HYDROLOGIC models, WATERSHED management

Abstract

Streamflow observations can be used to understand, predict, and contextualize hydrologic, ecological, and biogeochemical processes and conditions in streams. Stream gages are point measurements along rivers where streamflow is measured, and are often used to infer upstream watershed‐scale processes. When stream gages read zero, this may indicate that the stream has dried at this location; however, zero‐flow readings can also be caused by a wide range of other factors. Our ability to identify whether or not a zero‐flow gage reading indicates a dry fluvial system has far reaching environmental implications. Incorrect identification and interpretation by the data user can lead to inaccurate hydrologic, ecological, and/or biogeochemical predictions from models and analyses. Here, we describe several causes of zero‐flow gage readings: frozen surface water, flow reversals, instrument error, and natural or human‐driven upstream source losses or bypass flow. For these examples, we discuss the implications of zero‐flow interpretations. We also highlight additional methods for determining flow presence, including direct observations, statistical methods, and hydrologic models, which can be applied to interpret causes of zero‐flow gage readings and implications for reach‐ and watershed‐scale dynamics. Such efforts are necessary to improve our ability to understand and predict surface flow activation, cessation, and connectivity across river networks. Developing this integrated understanding of the wide range of possible meanings of zero‐flows will only attain greater importance in a more variable and changing hydrologic climate. This article is categorized under:Science of Water > MethodsScience of Water > Hydrological ProcessesWater and Life > Conservation, Management, and Awareness [ABSTRACT FROM AUTHOR]

Published

2020

6. Understanding controls on flow permanence in intermittent rivers to aid ecological research: integrating meteorology, geology and land cover.

Author

Costigan, Katie H., Jaeger, Kristin L., Goss, Charles W., Fritz, Ken M., and Goebel, P. Charles

Subjects

RIVER channels, STREAMFLOW, REGULATION of rivers, ECOLOGICAL research, METEOROLOGY, GEOLOGY, LAND cover

Abstract

Intermittent rivers, those channels that periodically cease to flow, constitute over half of the total discharge of the global river network and will likely increase in their extent owing to climatic shifts and/or water resources development. Burgeoning research on intermittent river ecology has documented the importance of the meteorologic, geologic and land-cover components of these ecosystems on structuring ecological communities, but mechanisms controlling flow permanence remain poorly understood. Here, we provide a framework of the meteorologic, geologic and land-cover controls on intermittent streamflow across different spatio-temporal scales and identify key research priorities to improve our understanding of intermittent systems so that we are better able to conserve, manage and protect them. Copyright © 2015 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2016

7. Implementing an Operational Framework to Develop a Streamflow Duration Assessment Method: A Case Study from the Arid West United States.

Author

Mazor, Raphael D., Topping, Brian J., Nadeau, Tracie-Lynn, Fritz, Ken M., Kelso, Julia E., Harrington, Rachel A., Beck, Whitney S., McCune, Kenneth S., Allen, Aaron O., Leidy, Robert, Robb, James T., and David, Gabrielle C. L.

Subjects

STREAMFLOW, EPHEMERAL streams, RANDOM forest algorithms, BIOINDICATORS

Abstract

Streamflow duration information underpins many management decisions. However, hydrologic data are rarely available where needed. Rapid streamflow duration assessment methods (SDAMs) classify reaches based on indicators that are measured in a single brief visit. We evaluated a proposed framework for developing SDAMs to develop an SDAM for the Arid West United States that can classify reaches as perennial, intermittent, or ephemeral. We identified 41 candidate biological, geomorphological, and hydrological indicators of streamflow duration in a literature review, evaluated them for a number of desirable criteria (e.g., defensibility and consistency), and measured 21 of them at 89 reaches with known flow durations. We selected metrics for the SDAM based on their ability to discriminate among flow duration classes in analyses of variance, as well as their importance in a random forest model to predict streamflow duration. This approach resulted in a "beta" SDAM that uses five biological indicators. It could discriminate between ephemeral and non-ephemeral reaches with 81% accuracy, but only 56% accuracy when distinguishing 3 classes. A final method will be developed following expanded data collection. This Arid West study demonstrates the effectiveness of our approach and paves the way for more efficient development of scientifically informed SDAMs. [ABSTRACT FROM AUTHOR]

Published

2021

8. Beyond Streamflow: Call for a National Data Repository of Streamflow Presence for Streams and Rivers in the United States.

Author

Jaeger, Kristin L., Hafen, Konrad C., Dunham, Jason B., Fritz, Ken M., Kampf, Stephanie K., Barnhart, Theodore B., Kaiser, Kendra E., Sando, Roy, Johnson, Sherri L., McShane, Ryan R., and Dunn, Sarah B.

Subjects

STREAMFLOW, STREAM measurements, RIVER channels, ACQUISITION of data, CROWDSOURCING

Abstract

Observations of the presence or absence of surface water in streams are useful for characterizing streamflow permanence, which includes the frequency, duration, and spatial extent of surface flow in streams and rivers. Such data are particularly valuable for headwater streams, which comprise the vast majority of channel length in stream networks, are often non-perennial, and are frequently the most data deficient. Datasets of surface water presence exist across multiple data collection groups in the United States but are not well aligned for easy integration. Given the value of these data, a unified approach for organizing information on surface water presence and absence collected by diverse surveys would facilitate more effective and broad application of these data and address the gap in streamflow data in headwaters. In this paper, we highlight the numerous existing datasets on surface water presence in headwater streams, including recently developed crowdsourcing approaches. We identify the challenges of integrating multiple surface water presence/absence datasets that include differences in the definitions and categories of streamflow status, data collection method, spatial and temporal resolution, and accuracy of geographic location. Finally, we provide a list of critical and useful components that could be used to integrate different streamflow permanence datasets. [ABSTRACT FROM AUTHOR]

Published

2021

9. Classifying Streamflow Duration: The Scientific Basis and an Operational Framework for Method Development.

Author

Fritz, Ken M., Nadeau, Tracie-Lynn, Kelso, Julia E., Beck, Whitney S., Mazor, Raphael D., Harrington, Rachel A., and Topping, Brian J.

Subjects

STREAMFLOW, BIOINDICATORS, HYDROGRAPHY, REMOTE sensing, EPHEMERAL streams, WATER management

Abstract

Streamflow duration is used to differentiate reaches into discrete classes (e.g., perennial, intermittent, and ephemeral) for water resource management. Because the depiction of the extent and flow duration of streams via existing maps, remote sensing, and gauging is constrained, field-based tools are needed for use by practitioners and to validate hydrography and modeling advances. Streamflow Duration Assessment Methods (SDAMs) are rapid, reach-scale indices or models that use physical and biological indicators to predict flow duration class. We review the scientific basis for indicators and present conceptual and operational frameworks for SDAM development. Indicators can be responses to or controls of flow duration. Aquatic and terrestrial responses can be integrated into SDAMs, reflecting concurrent increases and decreases along the flow duration gradient. The conceptual framework for data-driven SDAM development shows interrelationships among the key components: study reaches, hydrologic data, and indicators. We present a generalized operational framework for SDAM development that integrates the data-driven components through five process steps: preparation, data collection, data analysis, evaluation, and implementation. We highlight priorities for the advancement of SDAMs, including expansion of gauging of nonperennial reaches, use of citizen science data, adjusting for stressor gradients, and statistical and monitoring advances to improve indicator effectiveness. [ABSTRACT FROM AUTHOR]

Published

2020