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Contributions to the biology of the muskellungeGammon, James R. January 1961 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1961. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 138-144).
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Contemporary muskellunge genetic resources in northern Wisconsin : impacts of supplemental stocking and genetic management zones /Murphy, Edward Lancaster. January 2009 (has links) (PDF)
Thesis (M.S.)--University of Wisconsin--Stevens Point, 2009. / Submitted in partial fulfillment of the requirements of the degree Master of Science in Natural Resoueces (Fisheries), College of Natural Resources. Includes bibliographical references (leaves 91-96).
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Annual and seasonal variability in growth of sympatric muskellunge (Esox masquinongy Mitchill) and northern pike (Esox lucius Linnaeus)Inskip, Peter Douglas. January 1980 (has links)
Thesis (M.S.)--University of Wisconsin--Madison. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 92-98).
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Feulgen microphotometry of periblast nuclei in the muskellunge embryo (Clupeiformes: Esocidae) /Bachop, William Earl January 1964 (has links)
No description available.
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Walleye and muskellunge movement in the Manitowish Chain of Lakes, Vilas County, Wisconsin /Weeks, Jordan. January 2006 (has links) (PDF)
Thesis (M.S.)--University of Wisconsin--Stevens Point, 2006. / Includes bibliographical references (leaves 37-43).
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MANAGING SPAWNING AND NURSERY HABITAT OF THE GEORGIAN BAY MUSKELLUNGE (ESOX MASQUINONGY)Leblanc, John Paul MR 08 1900 (has links)
The self-sustaining status of Georgian Bay’s trophy muskellunge (Esox masquinongy) fishery is owed in part to the widespread distribution of high quality coastal wetlands used as nursery habitat. The specific wetland features that promote the recruitment of young-of-the-year (YOY) muskellunge in Georgian Bay have not been clearly defined, and without such information, it is unclear to what extent an unprecedented period of sustained low water-levels (c. 1999), and/or shoreline modifications, will continue to degrade the suitability of nursery habitats used by muskellunge throughout Georgian Bay. In this thesis, I use data from two years of intensive sampling in two embayments of northern Georgian Bay to statistically differentiate between wetlands that were found with and without YOY muskellunge. By doing so, I have provided the first quantifiable definition of suitable nursery habitat for muskellunge in Georgian Bay. Muskellunge nurseries have a structurally complex community of submersed aquatic vegetation (SAV; e.g. Potamogeton richardsonii) within the water column (≤ 1-m depth) and a fish community that had abundant suitable prey (e.g. Cypinid species) and a scarcity of early-life predators (e.g. Perca flavescens). Some key aspects of the SAV community were governed by wetland's bathymetry, and this relationship makes it possible to model the effect of changing water-level scenarios on habitat suitability.
I translated these results into a management tool for fish management agencies by creating an Index of Nursery Habitat Suitability (INHS) that can be applied to other embayments in Georgian Bay to identify high quality early-life habitats for muskellunge. I developed two INHS models and applied them to an independent dataset from other regions of Georgian Bay, and found them to differentiate between sites that were known to be used by YOY muskellunge and those where YOY were absent. These were also able to track deterioration in habitat quality associated with the recent decade of low water levels. Both INHS models rely on variables based on robust ecological relationships known to favour YOY survivorship that can be readily collected by fish management agencies, and one INHS model does not require detailed information of the aquatic plant community. Both models were also designed to minimize the frequency of false negatives (suitable nursery sites misidentified as unsuitable) and false positives (unsuitable nursery sites misidentified as suitable). These INHS models should become an important tool that will complement harvest regulations to promote this economically and ecologically valuable, self-sustaining muskellunge population in Georgian Bay. / Thesis / Doctor of Philosophy (PhD) / The following Ph.D. describes how a period of sustained low water levels and shoreline modifications in Georgian Bay, Lake Huron, have impacted the coastal wetland habitat used by muskellunge during their early life. To counteract these adverse effects, the thesis provides a definition of the wetland features that promote the survival of young-of-the-year muskellunge in Georgian Bay. Included is a proposed management tool in the form of an Index of Nursery Habitat Suitability (INHS) for muskellunge that can be used to identify high-quality, early-life habitat of muskellunge. Furthermore, the INHS can be used to predict how the quality of this habitat responds to different water-level scenarios and to shoreline modification in Georgian Bay, and to guide rehabilitative efforts of degraded wetland habitat.
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Stock Structure, Management, and Phylogeography of MuskellungeKohli, Brooks A. 16 June 2010 (has links)
No description available.
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Evaluation of Current Management Strategies for the New River, Virginia, Muskellunge Fishery: Modeling the Effect of Alternative Harvest Regulations and Habitat SelectionBrenden, Travis Owen 26 April 2005 (has links)
The purpose of this research was to evaluate current management strategies for the New River, Virginia, muskellunge Esox masquinongy fishery, which is the premier muskellunge fishery in the state. The primary objectives were to evaluate potential benefits and angler support for more restrictive harvest regulations and to quantify habitat selection at multiple spatial scales. A secondary objective was to develop an alternative procedure for testing differences in muskellunge condition from relative weight Wr data that incorporates uncertainty regarding the accuracy of the standard weight equation and that is based on derived statistical properties of the Wr index. Abundance of memorable-length (³1,070 mm) muskellunge was predicted to increase with minimum length limits of 914, 1,016, and 1,143 mm. Although yield per recruit would decline under a 1,143-mm minimum length limit, it was predicted to remain fairly stable at length limits of 914 and 1,016 mm due to fast growth rates of young fish. Even though most anglers defined trophy muskellunge to be in excess of 1,016 mm, angler support for length limits in excess of 1,000 mm was low. Habitat variables that were most strongly related to muskellunge habitat selection were measures of patch shape complexity and water depth. Increased river discharge was found to significantly affect muskellunge habitat use and selection, with fish abandoning deeper open-water habitats and moving to shallower areas closer to the shoreline during periods of high discharge. As for the secondary objective, a new statistical test (R-test) was developed that can be used to test for differences in Wr between and within fish stocks. Comparison with other statistical tests indicated that the R test provides more conservative results than traditional statistic procedures, and that substantial variability in standard weight equations will make it more difficult to detect statistical differences. Management recommendations for the New River muskellunge fishery include increasing the minimum length limit to approximately 965 to 1,067 mm and limiting the stocking of muskellunge only to those areas with sufficient juxtaposition of shallow- and deep-water habitat patches. / Ph. D.
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Managing Muskellunge in the New River, Virginia: Effective Regulations and Predation on Smallmouth BassDoss, Sasha Stevely 21 April 2017 (has links)
Potential predation between fishes of recreational interest has incited many bitter conflicts between angler groups. Large predators, such as esocids, are often at the center of these conflicts because of their capacity to alter fish populations. Such a conflict certainly exists between the Muskellunge Esox masquinongy and Smallmouth Bass Micropterus dolomieu fisheries of the New River, Virginia. Following the institution of a 42-in minimum-length limit (MLL) on Muskellunge, bass anglers feared that increased Muskellunge abundance might be negatively affecting Smallmouth Bass via increased predation. In order to ascertain the impacts of the 42-in MLL, I estimated the demographics, abundance, and food habits of Muskellunge combined with bioenergetics modeling to assess changes (i) in the quality of the Muskellunge fishery and (ii) in Muskellunge predation on Smallmouth Bass. Additionally, given the likelihood of future regulations to incite similar concerns from bass anglers, I modeled alternative length-limit regulations (iii) to assess their potential to improve fishery quality, thereby laying the groundwork for managers to address angler concerns before they arise. I found substantial increases in population size structure and in average adult density of Muskellunge since the institution of the 42-in MLL, but bioenergetics modeling did not indicate a notable increase in the consumption of Smallmouth Bass. I also found that high MLLs (e.g., 48-in) were likely to promote the largest increases in trophy production of Muskellunge compared to low MLLs or protected-slot limits (PSLs). This study suggests that the current Muskellunge population likely plays a small role in shaping Smallmouth Bass population dynamics and production in the New River; and lays the groundwork for predicting how the impact of Muskellunge on Smallmouth Bass might change under alternative regulations. / Master of Science / Management of fish for recreation can be challenging when multiple species are of interest, particularly when potential exists for one species to negatively influence another and stimulates conflict between users. Large predators are often at the center of these conflicts because of their ability to change fish populations via predation. This type of conflict certainly exists between the Muskellunge <i>Esox masquinongy</i> and Smallmouth Bass <i>Micropterus dolomieu</i> fisheries of the New River, Virginia. The perceived influence of increased Muskellunge predation on Smallmouth Bass and the bass fishery following the institution of a 42-in minimum-length limit (MLL), has created tension between users. In order to ascertain the impacts of the 42-in MLL, I estimated Muskellunge population structure, abundance, and food habits and combined them with diet modeling to assess changes (i) in the number and size of Muskellunge and (ii) in Muskellunge predation on Smallmouth Bass. Additionally, given the likelihood of future regulations to incite similar concerns from bass anglers, I also used regulation modeling to assess (iii) the potential of other regulations to change the number and size of Muskellunge. I found that the size structure (i.e., the proportion of large Muskellunge in the population) and the number of Muskellunge increased after the 42-in MLL, but I did not find a notable increase in the amount of Smallmouth Bass eaten by Muskellunge. I also found that more-restrictive regulations (i.e., a 48-in MLL) could further increase the size structure and number of Muskellunge. My results suggest that the current Muskellunge population probably plays a small role in shaping the Smallmouth Bass population of the New River, and I lay the groundwork for predicting how that role might change under other regulations.
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Habitat-use and emigration patterns of two top predators stocked in a large flood-control impoundmentShane, Keith Dennis January 2018 (has links)
No description available.
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