Hydroclimate reconstructions of the Potomac River Basin using tree rings

Maxwell, Richard Stockton.

January 1900

Thesis (Ph. D.)--West Virginia University, 2010. / Title from document title page. Document formatted into pages; contains vii, 102 p. : ill. (some col.), maps (some col.). Vita. Includes abstract. Includes bibliographical references.

Renegotiating the Edge: Creating an Inspired Reality in the Potomac River Watershed

Tacey, Carlin Renee

22 June 2017

Water edge communities are portals to terra firma. Their role as negotiators between land and water is more important now than ever before due to increasing fluctuations in water height from storm surges and sea level rise. To understand the future of these edge conditions, my research looks to the past at a 1967 report entitled; The Potomac: A Report on Its Imperiled Future and a Guide for Its Orderly Development, authored by pioneers Stewart Udall, Ian McHarg and others. The report approached the ecology and culture of the Potomac River basin through the lens of the 1960s, a time of unprecedented growth. Emerging at the semi-centennial of the original report, my thesis is both an homage and critique, challenging its concepts of order and development, and redefining four of the original eleven principles in the report's concept of the ideal region. The thesis investigation also works within a more actionable scale of intervention, a tributary to the Potomac River. The project develops a transferable approach for other tributaries, exploring Quantico Creek and the town of Dumfries, Virginia, a historic seaport in Prince William County, as a case study for design intervention, and analyzes the historic and ecological conditions that led to the marginalization of the community in the wake of siltation and urban sprawl. The resulting proposal reconnects the community with the creek, and fulfills an intention of the original Potomac Report: to spark inspired realities along the river's 400-mile course. / Master of Landscape Architecture

landscape architecture

waterfront

urban planning

Potomac River

Planktonic foraminiferal biostratigraphy and correlation of the aquia formation in the type area, along the Potomac River, Virginia

Faris, Craig Duncan

January 1982

Planktonic Foraminifera were examined from the Aquia Formation (Late Paleocene) from 2 localities in the Aquia type area along the Potomac River 7 miles southeast of Stafford, Virginia to: identify taxa present, and to effect biostratigraphic correlation with other Paleocene studies on the Virginia Coastal Plain. Two genera and twenty-two species were recovered, allowing recognition of the Globorotalia pseudomenardii and Globorotalia velascoensis zones, and correlation with The Oak Grove Core, 23 miles to the southeast (Gibson, et al. 1980), and a Pamunkey River locality 50 miles to the south (Seaton, 1982). This correlation shows equal thicknesses of the Aquia within zonal boundaries over the Potomac River - Oak Grove - Pamunkey River area, suggesting uniform rates of Aquia sedimentation in this portion of the Salisbury Embayment. Correlation of the Oak Grove Core, which was zoned via the Tertiary NP zonation indicates the presence of NP zones 5,6-?7,8,9 in the Aquia type area. / Master of Science

LD5655.V855 1982.F372

Foraminifera -- Potomac River

George Washington and the improvement of the Potomac, 1754-85

Albert, Peter Joseph,

January 1969

Thesis (M.A.)--University of Wisconsin--Madison, 1969. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Secession, war and rebirth the Civil War in West Virginia's South Branch Valley of the Potomac /

Smith, Stephen G.

January 2000

Thesis (Ph. D.)--West Virginia University, 2000. / Title from document title page. Document formatted into pages; contains iv, 278 p. : maps. Includes abstract. Includes bibliographical references (p. 258-272).

A real time model of nitrogen-cycle dynamics in an estuarine system.

Najarian, Tavit Ohannes.

January 1975

Thesis: Sc. D., Massachusetts Institute of Technology, Department of Civil Engineering, 1975 / Vita. / Bibliography: leaves 266-271. / Sc. D. / Sc. D. Massachusetts Institute of Technology, Department of Civil Engineering

Civil Engineering

Eutrophication.

Nitrogen cycle.

Where land ends: a water museum on the Potomac

West, Gerrie King

January 1984

no abstract provided by author / Master of Architecture

LD5655.V855 1984.W477

Potomac River

Impact of Indirect Potable Reuse on Endocrine Disrupting Compounds in the Potomac River Basin

Flanery, Amelia Lynn

17 June 2020

The Potomac River Basin is significant for both public and ecological health as it flows directly into the ecologically-sensitive Chesapeake Bay. It is a drinking water source for about 5 million people living in Maryland, Virginia, and Washington D.C. The discovery of intersex fish, an indicator of poor ecological health, in the Chesapeake Bay occurred in the 2000s, and has led to a series of studies in the watershed to determine the sources and magnitude of endocrine disruption. Endocrine disrupting compounds (EDCs) are exogenous chemicals that interfere with the endocrine system and can cause detrimental health effects at low concentrations. This study aims to understand a best management practice referred to as planned indirect potable reuse (IPR) and its impacts on EDCs. The Occoquan Watershed is a planned IPR subwatershed of the Potomac River Basin. Water samples were collected at the water reclamation plant discharge (Upper Occoquan Service Authority), up- and downstream of that location along Bull Run, and at the water treatment plant intake (Frederick P. Griffith WTP) in the Occoquan Watershed to assess planned IPR. Samples were also collected at a water treatment plant (James J. Corbalis WTP) along the Potomac River for comparison as an unplanned IPR location. These two groups of samples were analyzed for EDCs (categorized into two groups: estrogen hormones and other synthetic organic compounds (SOCs)), nutrients, and other water quality parameters. The infrequency of estrogen hormones and SOC patterns indicate planned and unplanned IPR are both viable approaches to provide safe drinking water / Master of Science / Our river systems are important to maintain both for human and environmental health. The Potomac River Basin is the area of land drained by the Potomac River and its tributaries. The Potomac River Basin is significant for both public and ecological health as it flows directly into the ecologically-sensitive Chesapeake Bay. It is a drinking water source for about 5 million people living in Maryland, Virginia, and Washington D.C. The discovery of intersex fish, or when a single fish has both male and female characteristics, occurred in the Chesapeake Bay in the 2000s. Fish health is often an indicator of poor environmental health, and in this case endocrine disruption. This discovery led to a series of studies in the watershed to determine the sources and magnitude of endocrine disruption. Endocrine disrupting compounds (EDCs) are external chemicals that interfere with the endocrine system once they enter the body of a human or another organism, and can cause detrimental health effects even at low concentrations. This study aims to understand a best management practice, or a type of water pollution control, referred to as planned indirect potable reuse (IPR) and its impacts on EDCs. IPR occurs when wastewater from a community is discharged into to a river or a reservoir, and then downstream it is withdrawn from that same source for drinking water purposes. This can be either planned or unplanned. Planned IPR is becoming more common as population, especially in urban areas, increases. The Occoquan Watershed is a planned IPR subwatershed of the Potomac River Basin. Water samples were collected at the water reclamation plant discharge (Upper Occoquan Service Authority), up- and downstream of that location along Bull Run, and at the water treatment plant intake (Frederick P. Griffith WTP) in the Occoquan Watershed to assess planned IPR. Samples were also collected at a water treatment plant (James J. Corbalis WTP) along the Potomac River for comparison as an unplanned IPR location. These two groups of samples were analyzed for EDCs (categorized into two groups: estrogen hormones and other synthetic organic compounds (SOCs)), nutrients, and other water quality parameters. The infrequency of estrogen hormones and SOC patterns indicate planned and unplanned IPR are both viable approaches to provide safe drinking water.

synthetic organic compounds

endocrine disrupting compounds

indirect potable reuse

Potomac River

An ecological survey of the Potomac and Anacostia Rivers with special emphasis on pollution

Bradley, Martha C.

January 1959

Thesis--Catholic University of America. / Bibliography: p. 31-33.

Maintaining a Nitrogen Cap for Virginia's Potomac River: The Contribution of Alternative Development Patterns

Doley, Todd Michael

05 February 1999

The Chesapeake Bay, once one of the worlds most productive estuaries, has been severely impacted by human activity in the water and on the lands around it. Viewed as an ecosystem, the Bay is no longer able to support the variety and abundance of biota that it was historically able to. Several decades of research on the Chesapeake have pointed to human activities as being the principle reason for this decline. Of these detrimental activities, elevated inputs of Nitrogen and Phosphorus to the Bay were singled out as being the greatest cause of water quality deterioration. The state of Virginia is trying to reduce its annual load of Nitrogen, to the Potomac River, to 60% of what the load was estimated to be in 1985. Virginia would like to accomplish this goal at the lowest cost to its citizens. Therefore the state needs to determine the combination of nitrogen control efforts which will achieve the goal at the lowest cost. The state would also like to be able to maintain nitrogen loads at or below this cap level, indefinitely into the future. This study was undertaken with three primary objectives. The first was to project the level of annual nitrogen inputs to the Potomac River, from the state of Virginia, over the next 15 years. The second was to estimate the minimum annual costs necessary to achieve and maintain a 40% reduction in total nitrogen inputs, using the Virginia's estimated 1985 inputs as a baseline. The final objective was to assess the potential cost savings that may result from using one of two alternative development patterns within the rapidly urbanizing Northern Virginia portion of the Potomac Watershed. The first alternative is prohibiting low-density development within the Northern Virginia region, and the second is to restrict all new development to be within 5 miles of an existing urban area. Study results suggest that there has been no significant progress toward meeting the nitrogen reduction goal, due to the increase in population within the watershed, over the past 13 years. To attain the goal in 1998, a minimum of $27 million, above what is currently being spent annually, would be required. Under the current land use trend within Virginia's Potomac Basin, the annual cost for maintaining the goal is estimated to rise to $38 million annually, in 1998 dollars, by the year 2013. This is a 40% increase in cost. If the first alternative development pattern is adhered to over this 15-year period, then the annual cost will be $33 million, for an annual cost saving of approximately $5 million in 2013. The second alternative could achieve similar results if implemented, costing roughly $5 million less in 2013 than the annual cost per year under the current trend. These findings suggest that the use of alternative development patterns can help slow but not prevent the annual cost, of maintaining the cap, from rising. The study indicates that the reason for the continuous rise in annual cost, over this fifteen-year period, is due primarily to an increase in nitrogen loading to the Potomac that will result from the wastewater disposal needs of the growing population within the Basin. Furthermore, the state will eventually exhaust its lower cost options for reducing Nitrogen loadings, and at that point the annual cost for maintaining the Nitrogen Cap will begin to rise exponentially. Under current land use trends this rapid rise in cost is unlikely to occur within the next 15 years, and is more apt to occur sometime within the next 20 to 40 years. Once annual expenditures begin to rise exponentially it is unlikely that the state of Virginia would be able to maintain its 40% reduction goal. / Master of Science

Potomac River

Nutrient Enrichment

Watershed

Northern Virginia

Tributary Strategy

Chesapeake Bay

Land Use

Shenandoah

Sprawl

Water Quality

Best Management Practice

Alternative Development Patterns

Cost-Effectiveness