Stable isotope geochemistry of nitrogen in marine particulates

Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at the Massachusetts Institute of Technology and the Woods Hole Oceanographic Institution January 1983Isotope studies of nitrogen and carbon were undertaken to investigate the fate of particulate organic matter (POM) during its residence in the water column and after deposition on the seafloor. The processes focused on were water-column transformations and sedimentary diagenesis. Sampling sites were chosen to provide POM subject to different specific mineralization processes (nitrification, denitrification, and sulfate reduction), different lengths of water column (duration of the mineralization process), and differences in the size of the organic-matter flux. The δl5N and δ13C of plankton, POM, and sediments from several oceanic sites were related to biological and hydrographic processes identified from nutrient, temperature, and salinity profiles. This was done to determine what effect these processes have on the δ15N of POM. Four stations were studied in the upwelling area off the coast of Peru and one station was studied in the Gulf of Maine. Important factors controlling the δ15N of plankton appear to be the concentration and δl5N of nitrate in the surface waters, and the relative zooplankton and phytoplankton abundances. Plankton from the Peru Upwelling Area are enriched in 15N as compared to plankton from other parts of the world's oceans where denitrification is absent. This enrichment may be due to the assimilation of 15N-enriched nitrate, produced by the selective reduction of 14N during denitrification. Zooplankton are 3 to 4% enriched in 15N as compared with phytoplankton. Production of 14N -enriched fecal pellets is suggested as a mechanism for this trophic enrichment. In the surface waters, the δl5N of POM is similar to that of plankton. In the Peru Upwelling Area, the δ15N of POM from the oxygen-deficient waters decreases with increasing depth. In the Gulf of Maine, below the euphotic zone in the oxic deep waters, the δ15N of POM increases with increasing depth. The difference in isotopic alteration may be due to the effect of different redox conditions on the mechanism and sequence by which specific organic nitrogen compounds, variably enriched in 15M, undergo degradation. Furthermore, bacterial growth on nitrogen-poor particles in the deep waters of the Peru Upwelling Area may contribute to the low δ15N of POM. In contrast to the large range in δ15N (-2 to +17%) of the POM, the range of δ15N in the sediments is small (+5 to +9%). Within a core, the average variation in δ15N was only 1.8%. Temporal variability in the δ15N of sedimenting POM and benthic activity appear to be important in determining the δ15N of the sediments. The large changes in POM concentration and isotope content at the sediment/water interface as compared with the more constant values found down-core, suggest that processes occuring at the sediment/water interface are critical, although bioturbation may also be important in determining the δ15N of oxic sediments. If diagenesis causes a significant loss of organic matter, profiles of organic carbon and nitrogen contents should show decreases with increasing depth and C/N ratios should increase with increasing depth (Reimers, 1981). Since none of the sedimentary profiles exhibited such trends, it is concluded that diagenesis was insufficient to erase the percent carbon, nitrogen and C/N ratio signatures generated by the POM flux and alterations at the sediment/water interface. Temporal variability in the δ15N of bottom-water POM may be caused by changes in deep-water currents which transport POM horizontally and to changes in bacterial and possibly other biological activity in the water column. This thesis work suggests that δ15N may be a useful tool in studying the geochemistry of POM in the marine environment. In addition, this research has shown that interpretation of the sedimentary 15N record must include consideration of isotopic alteration associated with bacterial remineralization of POM and benthic activity.Funds for this research were provided by the Massachusetts Institute of Technology / Woods Hole Oceanographic Institution Joint Program in Oceanography, the National Science Foundation under Grant No. OCE-8024442, and the Andrew W. Mellon Foundation through the Center for Coastal Research of the Woods Hole Oceanographic Institution

Review on wildlife value orientation for ecotourism resource management

Wildlife value orientation (WVO) is important in the management of conflicts in ecotourism, particularly in human and wildlife concerns as human-wildlife conflict reported cases have increased in recent years. Therefore, this article systematically reviews literatures on WVO globally from the context of theoretical approach as well as the effect of modernization on values towards wildlife. The theoretical approach highlights the cognitive hierarchy model and the development of four theories that shapes the cultural thought towards wildlife relevant to ecotourism products. By understanding, through integrated empirical investigation, the values people hold towards wildlife, it enables the development of effective decision makings in handling the conflicts in the realm of ecotourism product or resource management

Benthic pH gradients across a range of shelf sea sediment types linked to sediment characteristics and seasonal variability

This study used microelectrodes to record pH profiles in fresh shelf sea sediment cores collected across a range of different sediment types within the Celtic Sea. Spatial and temporal variability was captured during repeated measurements in 2014 and 2015. Concurrently recorded oxygen microelectrode profiles and other sedimentary parameters provide a detailed context for interpretation of the pH data. Clear differences in profiles were observed between sediment type, location and season. Notably, very steep pH gradients exist within the surface sediments (10–20 mm), where decreases greater than 0.5 pH units were observed. Steep gradients were particularly apparent in fine cohesive sediments, less so in permeable sandier matrices. We hypothesise that the gradients are likely caused by aerobic organic matter respiration close to the sediment–water interface or oxidation of reduced species at the base of the oxic zone (NH4+, Mn2+, Fe2+, S−). Statistical analysis suggests the variability in the depth of the pH minima is controlled spatially by the oxygen penetration depth, and seasonally by the input and remineralisation of deposited organic phytodetritus. Below the pH minima the observed pH remained consistently low to maximum electrode penetration (ca. 60 mm), indicating an absence of sub-oxic processes generating H+ or balanced removal processes within this layer. Thus, a climatology of sediment surface porewater pH is provided against which to examine biogeochemical processes. This enhances our understanding of benthic pH processes, particularly in the context of human impacts, seabed integrity, and future climate changes, providing vital information for modelling benthic response under future climate scenarios

A review of nitrogen isotopic alteration in marine sediments

Key Points: Use of sedimentary nitrogen isotopes is examined; On average, sediment 15N/14N increases approx. 2 per mil during early burial; Isotopic alteration scales with water depth Abstract: Nitrogen isotopes are an important tool for evaluating past biogeochemical cycling from the paleoceanographic record. However, bulk sedimentary nitrogen isotope ratios, which can be determined routinely and at minimal cost, may be altered during burial and early sedimentary diagenesis, particularly outside of continental margin settings. The causes and detailed mechanisms of isotopic alteration are still under investigation. Case studies of the Mediterranean and South China Seas underscore the complexities of investigating isotopic alteration. In an effort to evaluate the evidence for alteration of the sedimentary N isotopic signal and try to quantify the net effect, we have compiled and compared data demonstrating alteration from the published literature. A >100 point comparison of sediment trap and surface sedimentary nitrogen isotope values demonstrates that, at sites located off of the continental margins, an increase in sediment 15N/14N occurs during early burial, likely at the seafloor. The extent of isotopic alteration appears to be a function of water depth. Depth-related differences in oxygen exposure time at the seafloor are likely the dominant control on the extent of N isotopic alteration. Moreover, the compiled data suggest that the degree of alteration is likely to be uniform through time at most sites so that bulk sedimentary isotope records likely provide a good means for evaluating relative changes in the global N cycle

Why We Should All Be Waccamaw Waterwatchers

The history and future of Horry County are entwined with those of the Waccamaw River. Until the advent of bridges and paved roads in the 1930s, the Waccamaw was the major commercial transportation artery, making the river the center of business and residential life. In modern times, the river has evolved into a significant and unique commercial and recreational resource, supporting residential real estate development and ecotourism. The river is also a source of drinking water and a federally per­mitted receiving body for treated effluent. It is part of a vast watershed that controls water drainage and purity over two counties in North Carolina and two counties in South Carolina. Maintaining these often-conflicting functions will be central to enabling development and to sustaining the quality of life that stimulates development. The Waccamaw River is arguably the most significant body of water affecting the history and future of the region. Today the Conway Riverwalk attracts residents and visitors to a thriving commercial center with shops and restaurants, a park and marina, while the banks of the Waccamaw - from Winyah Bay to Lake Waccamaw in North Carolina - are experienc­ing unparalleled growth at the edge of a significant freshwater source for thousands of citizens. Polluted stormwater runoff from commercial and residential properties, changes in hydrology caused by ditching and draining wetlands, and the loss of pervious surfaces threaten the future of the Waccamaw and every­thing along its banks. Maintaining a clean, navigable river is essential for the health and welfare of future generations and for the pleasure of those who enjoy hunting, fishing, swimming, boating, hiking and birding. In many ways, the future of the Waccamaw defines the future quality of life for its residents and visitors. As I will describe, our collective efforts will be needed to solve our current problems and minimize future ones.https://digitalcommons.coastal.edu/dtsls/1008/thumbnail.jp

An Introduction to Marine Biogeochemistry

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Discussion de la Question I : Connaissance du milieu marin et estuarien

Lacombe Henri, Madelain François, Libes M. Discussion de la Question I : Connaissance du milieu marin et estuarien. In: L'hydraulique et la maitrise du littoral. Problèmes côtiers posés par le mouvement des sédiments et la pollution. Dix-huitièmes journées de l'hydraulique. Marseille, 11-13 septembre 1984. Tome 6, 1984