Browsing by Subject "shoreline change"
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Item Open Access A Physical and Controversial Analysis of Shoreline Change on North Carolina’s Barrier Islands(2010-04-24T16:14:02Z) Kelly, KatelinWith the density of development in North Carolina’s coastal counties at an unprecedented high, the encroaching ocean is met with a heightened sense of urgency by coastal property owners. In this urgent call for coastal managers and legislators to remedy coastal investments, there is not a clear consensus to the appropriate action or lack thereof. The physical complexity of the shoreline is such that no two segments are alike and every action has consequences, making the balance of tradeoffs a very controversial matter. This research uses the historical shoreline mapping of Springer’s Point nature preserve on the barrier island of Ocracoke to demonstrate the naturally dynamic system of an undeveloped, but historically and ecologically valued property. Subsequent interviews with professionals working on coastal management issues provide a firsthand account of the political complexity of North Carolina’s shoreline, particularly with the added variable of development. Professional perspectives regarding the state and fate of our shoreline shed light on the controversy that is further fueled by accelerated sea level rise and the consequential political pressures. While urgency sometimes leads to short-term solutions, the informed advice and proposals of these professionals offer potential long-term alternatives. The key to our shoreline’s future largely relies on the actions and legislation that we put in place today.Item Open Access An Analysis of the Correlation between Shoreline Curvature and Shoreline Change along the Gulf of Mexico and the Mid-Atlantic Coast of the United States(2016-04-26) Cheng, Yeeyan (Scarlet)Increasing human development along the coast, together with climate change and sea level rise, has drastically changed the shape of the coastline. Because of the widespread impacts of shoreline change, studies have been conducted by USGS and various researches, in attempt to understand shoreline change rates and its connection to local, regional, and global factors. However, one of such factor, shoreline curvature, is not well-addressed in current literature. As a continuation of work that was conducted by another student last year, the main objective of this project is to expand the scope of the study by examining the shorelines of Texas, and the rest of the East Coast (up till Long Island at New York) of the United States. More importantly, this study aims to investigate how different temporal and spatial scales contribute to different strength, or even direction of the correlation between shoreline curvature and shoreline change.Item Open Access Investigating Regional Patterns of Shoreline Change(2009) Lazarus, EliMy doctoral work stems from an original motivation to understand more closely why some areas of sandy coastlines erode and others accrete<—>an intriguing fundamental question and one of societal relevance wherever human coastal infrastructure exists. What are the physical processes driving shoreline change, and over what spatial and temporal scales are they manifest? If forces driving the littoral system change, how does the shoreline respond? Can we attribute observed patterns of shoreline change to a particular process?
Recent novel numerical shoreline-evolution modeling demonstrated that wave-driven gradients in alongshore sediment transport could produce self-organized, emergent features on spatial scales from sand waves to large-scale capes [Ashton et al., 2001], introducing a new theoretical perspective to the cross-shore-oriented considerations of the coastal scientific community. The unexpected model results inspired fresh hypotheses about shoreline pattern formation and the forcing mechanisms behind them.
One overarching hypothesis was that under regimes of high- and low-angle deep-water incident waves, alongshore shoreline perturbations grow or diffuse away, respectively. To test the hypothesis we looked for a correlation between shoreline curvature (showing perturbations to a nearly straight coastline) and shoreline change in observed measurements. High-resolution topographic lidar surveys of the North Carolina Outer Banks from 1996<–>2006 allowed robust, quantitative comparisons between shoreline surveys spanning tens of kms. In Chapter 1 [Lazarus and Murray, 2007] we report that over the last decade, at multi-km scales along the barrier islands, convex-seaward promontories tended to erode and concave-seaward embayments accrete<—>a pattern of diffusion consistent with the smoothing effects of alongshore-transport gradients driven by a low-angle wave climate. Why then, after a decade or more of smoothing, do plan-view bumps in the shoreline still persist? In Chapter 2 [Lazarus et al., in review] we compile evidence suggesting that (a) a framework of paleochannels may control the areas of persistent multi-km-scale shoreline convexity that (b) in turn drive decadal-term transient changes in shoreline morphology by (c) affecting gradients in wave-driven alongshore sediment transport.
In Chapter 3, a third investigation of large-scale coastal behavior, we explore an existing premise that shoreline change on a sandy coast is a self-affine signal wherein patterns of changes are scale-invariant, perhaps suggesting that a single process operates across the scales. Applying wavelet analysis<—>a mathematical technique involving scaled filter transforms<—>we confirm that a power law fits the average variance of shoreline change at alongshore scales spanning approximately three orders of magnitude (5<–>5000 m). The power law itself does not necessarily indicate a single dominant driver; beach changes across those scales likely result from a variety of cross-shore and alongshore hydrodynamic processes. A paired modeling experiment supports the conclusion that the power relationship is not an obvious function of wave-driven alongshore sediment transport alone.
Our tests of theory against field observations are middle steps in pattern-to-process attribution; they fit into a larger body of coastal morphodynamic research that in time may enable shoreline-change prediction. Present hydrodynamic models are still too limited in spatial and temporal scope to accommodate the extended scales at which large morphological changes occur, but more integrated quantitative models linking bathymetry, wave fields, and geologic substrate are underway and will set the next course of questions for the discipline.
Item Open Access Natural Resource Management at South Topsail Beach, NC(2007-08-31T19:43:12Z) Wright, KatherineThe undeveloped southern tip of Topsail Island, NC, known as South Topsail Beach, has been accreting land and extending southwest into New Topsail Inlet at the rate of approximately 100 feet per year for the past decade, growing to its current size of roughly 135 acres. The dynamic coastal processes that dominate this landscape create habitat that the federally threatened shorebird the piping plover (Charadrius melodus), the loggerhead sea turtle (Caretta caretta), and the annual plant seabeach amaranth (Amaranthus pumilus) depend on for survival. Human disturbance and loss of habitat due to shoreline stabilization are among the biggest threats to success of these species throughout their habitat range. This Masters Project, in the form of a management plan, seeks to address the needs of these threatened species, while allowing for traditional and passive recreational uses at South Topsail Beach. In an effort to better understand shoreline change at this location, and to inform management recommendations for South Topsail Beach, a geospatial analysis using LIDAR (light detection and ranging) data was performed. Areas of erosion and accretion on both sides of New Topsail Inlet were identified and volumetric change was calculated for the years 1996 through 2005. Beach profiles were created to more closely examine spatial changes. Monitoring shoreline change over time can be used as a management tool to indicate habitat size and quality on a local level. On a broader scale, this type of analysis may be used to identify additional undeveloped dynamic inlet habitat appropriate for conservation.Item Open Access Shoreline Change on the East Coast: Exploring the Role of Shoreline Curvature(2015-04-24) Liu, JiahongThe low sloping sandy shoreline of the East Coast is one of the most dynamic and complicated systems influenced by a series of factors. Shoreline curvature has been mentioned in several pieces of literature as one of these factors, as it influences the shaping processes of the shoreline through affecting the alongshore sediment transport. However, only a few quantitative research or evidence has been provided to show the curvature influence on shoreline change rate. Using the coastline contour data of the east coast, the curvature has been calculated and smoothed on different scales (1-km, 3-km and 5-km) in this project. The results of correlation analysis of selected shoreline segments in Florida and North Carolina indicate the existence of a significant correlation between curvature and shoreline change rate. The greatest coefficient was observed on the 3-km scale of selected shoreline segments, which is similar to previous foundings. The results also show that the strength of correlation varies from one location to another.