Breeding biology of the great blue heron in southwestern Lake Erie.

Edford, Lois Helen.

January 1976

Thesis (M.S.)--Ohio State University. / Bibliography: leaves 124-133. Available online via OhioLINK's ETD Center

Great blue heron.

Environmental contaminants and breeding biology of great blue herons in the Columbia River Basin /

Thomas, Carmen M.

January 1997

Thesis (M.S.)--Oregon State University, 1998. / Typescript (photocopy). Includes bibliographical references (leaves 81-92).

The ecology of Hong Kong Ardeidae (Aves) with special reference to the Chinese pond heron at the Mai Po Marshes Nature Reserve

Young, Llewellyn.

January 1993

Thesis (Ph. D.)--University of Hong Kong, 1993. / Includes bibliographical references (leaves 162-194).

Ardeidae Chinese pond heron

Aspects of great blue heron (Ardea herodias) foraging ecology in southwestern Lake Erie.

Parris, Robert Warren.

January 1979

Thesis (M.S.)--Ohio State University. / Bibliography: leaves 105-110. Available online via OhioLINK's ETD Center

Great blue heron. Animals

A Study of a Heron Nesting Colony

Leatham, Linden J.

01 May 1947

Herons are well known because of their gregarious nesting habits. Like many others of the lower orders of birds they nest together in pure or mixed colonies of many different combinations and under diverse living conditions. The population of different colonies may vary from a few pairs to many thousands of pairs depending upon the nature and extent of the breeding area, the food supply available and the protection afforded either by natural or artificial means. In Utah and adjacent areas of bordering states, many types of heron associations have been studied and reported by ornithological workers. reeding colonies of Treganza Herons, Black Crowned Night Herons and Snowy Herons in pure species associations and mixed communities have been recorded. The tendency of herons to associate with other unrelated orders of birds in nesting situations has also been noted. Such colonies as the Gull-Pelican-Heron associations of the Great Salt Lake Islands and the Heron-Cormorant communities of Cache Valley and Bass Pond Reservoir support this observation. At least eight different communal associations involving herons in the nesting season are known in Utah. The question of the economic status of herons has long been debated among ornithologists and those engaged in the propagation of wild life, especially fish culture. The fish eating propensities of herons are known all over the world. In some regions the birds are condemned as a menace by the sportsman and in other areas they are considered to be his benefactors. Adequate studies have not been published to definitely establish the economic status of this group of birds. It is the purpose of this thesis to contribute to the knowledge of Ornithology by a presentation of the writer's observations and findings on a colony of nesting herons, noting, especially, certain factors influencing the behavior of the birds, their relationships to other animals of the community, economic importance and development of the colony.

heron

nesting

zoology

Zoology

Habitat selection and time of breeding in the Great Blue Heron, (Ardea herodias)

Butler, Robert William

January 1991

This thesis examines the causes and consequences of habitat selection and timing of breeding of the Great Blue Heron (Ardea herodias). My general hypothesis was that the duration of low tides and seasonal abundance of prey strongly influenced the location of colony-sites; timing of the breeding season; habitat shifts; and the use of space by foraging herons of different age- and sex-classes. I studied Great Blue Herons along the Pacific coast of Canada for five breeding seasons and four winters. Breeding herons were studied at a colony of 85 to 100 pairs on Sidney Island near the town of Sidney, and periodic visits were made to about 40 other colonies around the Strait of Georgia, British Columbia. At Sidney, I studied the foraging behaviour, food availability, habitat use and reproductive success in detail. At other colonies, I recorded the reproductive success of herons, located their main feeding areas and searched for nests of a predator, the Bald Eagle. In the non-breeding season, I investigated the foraging behaviour, dispersion pattern and habitat shifts of juvenile and post-breeding adult herons in the Fraser River delta. I hypothesized that heron colony-sites were located near food supplies or away from predators. Twenty-nine of 33 colony-sites were located within 6 km of their main feeding site. The number of heron pairs was slightly greater where eagles nested in high abundance than where eagle abundance was low, contrary to the hypothesis that breeding herons avoid areas with active eagle nests. I hypothesized that herons began breeding in spring shortly after females acquired enough food energy to make eggs, or so chicks were in nests when food was most plentiful to their parents. Egg-laying began about 9 days after a female's daily food intake crossed an energy threshold of 1715 kJ/day, whereas the peak availability of food energy to adults occurred about 35 days before the peak food demands of their chicks. Food intake rates by adults increased gradually in March and April with the increasing duration of low tides and the inshore movement of fishes. Adult food intake rates reached a peak in May when sea perch were most abundant, and diminished through June and July. Most juvenile and adult female herons foraged on beaches from February to October and in marshlands and grasslands from November to January. Some males returned to territories along riverbanks in August and remained there until the start of the next breeding season in March. I tested the hypothesis that herons leave foraging habitats in autumn when they can no longer catch enough food or when interference from conspecifics reduced foraging intake rates below a threshold required to maintain their energy balance. In October and November adults moved to marshlands and juveniles moved to grasslands when they could no longer maintain daily energy balance on beaches as a result of declining duration of low tides and food intake rates. Interference competition was too infrequent to explain habitat shifts by adult or juvenile herons in autumn. / Science, Faculty of / Zoology, Department of / Graduate

Great blue heron -- Habitat

Great blue heron -- Breeding

An exploration of Fermat numbers

Curci, Allison Storm

05 January 2011

This report focuses on the discovery of Fermat numbers as well as the subsequent innovations in processes for finding factors of Fermat numbers. The property of the prime factors of Fermat numbers, as well as the connections between Fermat numbers and other areas of mathematics, is also discussed. / text

Fermat

Fermat numbers

Heron Triangles

Environmental contaminants, disturbance and breeding failure at a great blue heron colony on Vancouver Island

Moul, Ian E.

January 1990

Great Blue Herons (Ardea herodias) breeding near a pulp mill at Crofton B.C. failed to raise young in 1987 and 1988. Elevated levels of polychlorinated dibenzo-p-dioxins and polychlorinated dibenzo-furans were detected in their eggs. The highest 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) toxic equivalent level observed was 496 ng/kg (wet weight) in 1987 (Elliott et al. 1989). I compared the Crofton colony with a less contaminated colony on Sidney Island in 1988 and 1989. I examined three possible explanations for nesting failure: (i) abnormal nesting behaviour by parents because of contamination, (ii) disturbance by human activities, and (iii) predation by Bald Eagles (Haliaeetus leucocephalus), Northwestern Crows (Corvus caurinus) and Common Ravens (Corvus corax). The Crofton colony was successful in 1989 and 1990. Within the TCDD toxic equivalent range of 34 - 257 ng/kg (1989), I observed no abnormal heron nesting behaviour or reduction in numbers of chicks fledged. In 1988 the herons at Crofton were disturbed repeatedly by human activities. Bald Eagles were observed daily at both Crofton and Sidney Island. The heron colony on Sidney Island failed in 1989 and 1990. The failures on Sidney Island were thought to involve a disturbance by eagles followed by rapid removal of eggs and young chicks at unattended nests by crows and ravens. It is likely that disturbance and predation played a part in the failure at Crofton in 1988, but there remains the possibility that environmental contaminants may have increased the sensitivity of herons to disturbance and predation. / Land and Food Systems, Faculty of / Graduate

Rational and Heron Tetrahedra

Chisholm, Catherine Rachel

January 2004

Rational tetrahedra are tetrahedra with rational edges. Heron tetrahedra are tetrahedra with integer edges, integer faces areas and integer volume --- the three-dimensional analogue of Heron triangles. Of course, if a rational tetrahedron has rational face areas and volume then it is easy to scale it up to get a Heron tetrahedron. So we also use `Heron tetrahedra' when we mean tetrahedra with rational edges, areas and volume. The work in this thesis is motivated by Buchholz's paper {\it Perfect Pyramids} [4]. Buchholz examined certain configurations of rational tetrahedra, looking first for tetrahedra with rational volume, and then for Heron tetrahedra. Buchholz left some of the cases he examined unsolved and Chapter 2 is largely devoted to the resolution of these. In Chapters 3 and 4 we expand upon some of Buchholz's results to find infinite families of Heron tetrahedra corresponding to rational points on certain elliptic curves. In Chapters 5 and 6 we blend the ideas of Buchholz in [4] and of Buchholz and MacDougall in [7], and consider rational tetrahedra with edges in arithmetic (AP) or geometric (GP) progression. It turns out that there are no Heron AP or GP tetrahedra, but AP tetrahedra can have rational volume. They can also have one rational face area, although only one AP tetrahedron has been found with a rational face area and rational volume. For GP tetrahedra there are still unsolved cases, but we show that if GP tetrahedra with rational volume exist, then there are only finitely many. The faces of a rational GP tetrahedron are never rational. Much of the work in these two chapters also appeared in the author's Honours thesis, but has been refined and extended here, and is included to give a more complete picture of the work on Heron tetrahedra which has been done to date. In the final chapter we use a different approach and concentrate on the face areas first, instead of the volume. To make it easier (hopefully) to find tetrahedra with all faces having rational area, we place restrictions on the types of faces and number of different faces the tetrahedra have. / Masters Thesis

heron tetrahedra

rational tetrahedra

diophantine equations

Breeding biology of the great blue heron in southwestern Lake Erie

Edford, Lois Helen

January 1976

No description available.

Nest

heronry

nestlings

GREAT BLUE HERON

Elm