Riparian Vegetation and Land Cover along the Great Plains' White River

Cahlander-Mooers, Alex

06 February 2016

<p> Overall, the results of this study show that there are evident trends among the three ecoregions and delta of the White River. The forest stands of the Pine Ridge/Pierre Shale Ecoregion are the oldest along the river, as evidenced by aerial mapping going back into the 1930s and by the larger average trunk diameters of the trees. Historic aerial photographs for this ecoregion shows a relative static system from the 1930s-2010, with little destruction of existing or creation of new forests within the floodplain. Along with the older age of the forests, the stands in this ecoregion have the lowest floral diversity. The Pine Ridge/Pierre Shale forests are also unique along the river in that they are largely dominated by Acer negundo (box elder), a late-successional species that is largely absent from the forests of the other ecoregions. As the river continues downstream and enters the Badlands Ecoregion it gains size and volume, while its riparian forests decrease in patch size and tree density. Although the forests become smaller, the variety of communities and diversity of species increase. Unlike the Pine Ridge/Pierre Shale Ecoregion, the Badlands&rsquo; land cover was dynamic from the 1930s-2010, with increases in forest and declines in river channel area (-29%). Farther downstream and with a larger river channel, the River Breaks has even larger and more diverse riparian forests and the highest plant species richness and diversity among the ecoregions. The rate of land cover change was the greatest in the River Breaks, as the larger river has greater power for eroding existing communities and depositing sediment for recruitment. The area of riparian woody vegetation increased sharply from the 1930s-2010 (58%), while the area of channel declined (-20%). This ecoregion had the most perennial streamflow, with fewer zero flow days than in the upstream ecoregions. The Delta is unique as the only portion of the river where flows are affected by the Fort Randall Dam on the Missouri River. The impact of the reservoir on the area is evident, as it has the largest proportional area of forest along the river, as well as having the flora with the highest wetland affinity.</p>

Biology|Botany|Ecology

Investigating Late Woodland-Period aquatic catchments through freshwater mussel assemblage composition

Gilleland, Sarah

23 September 2016

<p> During the Late Woodland Period in the American Southeast, the amount of space that any individual group could exploit began to shrink, due to the presence of other groups on the landscape. Resource expansion occurred to augment food supplies, resulting in increased exploitation of mussel beds. Because mussels can be extremely sensitive to the characteristics of the waterways they live in, the specific habitat requirements of these animals can be used to reconstruct the environments they were recovered from. In this thesis I use freshwater mussel assemblages to reconstruct hypothetical aquatic catchments and map them onto modern rivers in the Yazoo River Basin and the Tombigbee River Basin. These are used to test ethnographic models of exploited space. I also use detrended correspondence analysis to test if sites exist in mathematical space like they do in physical space along the Yazoo River basin, as observed in the Tombigbee River basin.</p>

Biology|Archaeology|Ecology

Stoichiometric Homeostasis in Two Native and Two Invasive South Dakotan Grasses

Harvey, Joshua Thomas

03 May 2019

<p> Increased nutrient availability has been widely linked to the success of invasive plants, however a general mechanism explaining these observations is lacking. Stoichiometric homeostasis (<i>H</i>), which is the regulation of internal nutrient concentrations, has been used to explain changes in plant community diversity under alterations in nutrient availability. One hypothesis holds that plants with high regulation (larger <i>H</i>) decrease in abundance in nutrient enriched conditions but are stable in nutrient deficient and drought conditions, likely due to extensive root systems. Additionally, plants with low regulation (lower <i>H</i>) increase in abundance under nutrient enriched conditions but are sensitive to drought conditions. I tested the hypotheses that <i>H</i> would be higher in native grasses than in invasive grasses, that <i>H</i> would be modulated by environmental conditions, and that differences in <i>H</i> would be associated with differences in growth and biomass allocation. I calculated <i> H</i> and measured plant growth and growth traits in two native (<i> Pascopyrum smithii</i> and <i>Elymus canadensis</i>) and two invasive (<i>Bromus inermis</i> and <i>Agropyron cristatum </i>) grasses grown in two experiments. Both experiments contained a range of N:P fertilizer supply concentrations and the first experiment contained a two-level drought treatment while the second experiment contained a two-level mycorrhizal inoculation treatment. </p><p> In the first experiment, I found support for the hypothesis that <i> H</i> is higher in native than invasive plants, that environmental conditions (i.e. water availability) affect the value of <i>H</i>, and that differences in <i>H</i> were associated with differences in growth. In the second experiment, there was no successful mycorrhizal inoculation, resulting in no differences in <i>H</i> between mycorrhizal treatment groups. There were significant differences in total growth between the second experiment native and invasive grasses, despite there being no significant differences in <i>H</i>. Differences in <i>H</i> values between control-treated grasses in the two experiments may be due to differences in greenhouse temperature and light conditions. These results show first, significant differences exist in <i>H</i> between invasive and native grasses, with invasive grasses expressing lower values of <i> H</i>, second, environmental conditions effect the expression of <i> H</i>, and third, that differences in the expression of <i>H</i> are matched by differences in growth.</p><p>

Biology|Botany|Ecology

AMPHIPODS ARE STRONG INTERACTORS IN THE FOOD WEB OF A BROWN-WATER SALMON RIVER

Thompson, Audrey Marie

24 July 2007

Marine derived biomass from salmon carcasses is incorporated into coastal Pacific Rim salmon river systems via the organisms and structures of the freshwater foodweb. In brown water rivers of Western Kamchatka, the foodweb is dominated by ubiquitous benthic amphipods (Anisogammarus kygi) that consume salmon carcass material. We hypothesized that A. kygi are a strong interactor in the feedback loop which links dead spawner biomass to juvenile salmonid growth. We found that A. kygi had a complex life cycle with anadromous and resident forms. A. kygi dominated the macro-benthos, comprising more than 88.0% (SE=.01, N=7) of invertebrate biomass, and were highly mobile within the system, exhibiting upstream migrations of ovigerous females (23 ind/m3 ± 5), drift of juveniles, and re-distribution during carcass loading. A. kygi was observed feeding on 97% of salmon carcasses examined (N=100), making up 98.8% (SE .007) of invertebrate consumers, at densities up to 3,000 carcass-1. Amphipods were an important food item for rearing salmonids, especially during the summer when fish diets reached a peak of 88.7% (SE=6.0%) amphipods in 2005, and 68% (SE=18%) amphipods in 2006. The condition factor of salmonid juveniles (K) increased from spring to summer, particularly in juvenile chum, whose spring diet was 76.83% (SE 0.05) amphipods, corroborating the importance of an amphipod based diet for salmonids in this river. We concluded that A .kygi is a strong interactor in the Utkholok system. We also observed abundance of A. kygi in six other brown water rivers of western Kamchatka which suggests that the amphipod-mediated feedback of marine derived nutrients described for the Utkholok, is typical of brown water systems with salmon.

Organismal Biology and Ecology

Tidal exchange of decapod larvae and small benthic peracarids between the ocean and the Salmon River estuary, Oregon /

Gonzalez, Exequiel B.

January 1983

Thesis (M.S.)--Oregon State University, 1984. / Typescript (photocopy). Includes bibliographical references (leaves 37-41). Also available on the World Wide Web.

Marine biology. Marine ecology.

Plant speciation (I) Species delimitation and pollinator driven floral evolution in the Giliopsis group of Ipomopsis (Polemoniaceae). (II) Polyploidy and vascular plant diversity /

Wood, Troy E.

January 2009

Thesis (Ph.D.)--Indiana University, Dept. of Biology, 2009. / Title from PDF t.p. (viewed on Feb. 5, 2010). Source: Dissertation Abstracts International, Volume: 70-04, Section: B, page: 2009. Adviser: Loren H. Rieseberg.

Biology, Botany. Ecology.

The biology and ecology of the long rough dab, Hippoglossoides platessoides (Fabricius 1780) in the North Sea

Ntiba, Micheni J.

January 1989

No description available.

590

Fish biology and ecology

Indirect genetic effects of social environment influence the expression of antipredator behavior in guppies, Poecilia reticulata

Bleakley, Bronwyn H.

January 2007

Thesis (Ph.D.)--Indiana University, Dept. of Biology, 2007. / Source: Dissertation Abstracts International, Volume: 68-09, Section: B, page: 5787. Adviser: Edmund D. Brodie, III. Title from dissertation home page (viewed May 9, 2008).

Biology, Zoology. Ecology.

Application of molecular biology techniques in the assessment of microbial community respones to environmental perturbations /

Palmer, Sarah E.,

January 1991

Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1991. / Vita. Abstract. Includes bibliographical references. Also available via the Internet.

Molecular biology Microbial ecology.

An examination of host-parasite coevolution and negative frequency-dependent selection in a snail-trematode system

Koskella, Britt L.

January 2008

Thesis (Ph.D.)--Indiana University, Dept. of Biology, 2008. / Title from PDF t.p. (viewed on Jul 27, 2009). Source: Dissertation Abstracts International, Volume: 69-11, Section: B, page: 6617. Adviser: Curt M. Lively.

Biology, Parasitology. Ecology.