scholarly journals Synthesis of photochemical transformations of oil in the sea

2021 ◽  
Vol 2021 (1) ◽  
Author(s):  
Collin P. Ward ◽  
Edward B. Overton
Keyword(s):  
Crude Oil ◽  
Oil Spill ◽  
Research Question ◽  
Photochemical Oxidation ◽  
Relative Importance ◽  
Weathering Processes ◽  
Photochemical Transformations ◽  
Chemical Dispersant ◽  
Oil Spill Response ◽  
Physical And Chemical

Abstract: In this presentation and article, we synthesize findings from a workshop about our understanding of the interplay between crude oil photochemical oxidation and oil spill response, emphasizing how this understanding has evolved since the 2010 DWH spill. Our discussion is guided by one overarching questions: what role does photochemical oxidation play towards informing effective oil spill response operations? We show that prior to the DWH spill, our understanding of the relative importance of oil weathering processes, specifically photochemical weathering, was incomplete. We further explore how accounting for photochemical changes to oil's properties (physical and chemical) could improve the effectiveness of oil spill response operations, specifically chemical dispersant applications. Lastly, we identify priority knowledge gaps related to this guiding research question.

FATE OF CRUDE OIL SPILLED IN A SIMULATED ARCTIC ENVIRONMENT

1977 ◽  
Vol 1977 (1) ◽  
pp. 461-463 ◽  
Author(s):  
C. MacGregor ◽  
A. Y. McLean
Keyword(s):  
Crude Oil ◽  
Oil Spill ◽  
The Arctic ◽  
Oil Composition ◽  
Liquid Chromatograph ◽  
Weathering Processes ◽  
Mixing Energy ◽  
Ultimate Fate ◽  
Physical And Chemical ◽  
Crude Oil Spill

ABSTRACT A simulated Arctic crude oil spill was investigated by monitoring physical and chemical changes in a laboratory spill of Guanipa (Venezuelan) crude. The spill consisted of one gallon of crude on 100 gallons of synthetic seawater contained in a fiberglass tank fitted with a wave generator and a controlled radiation system, all located in an environmental chamber held at 2°C. Changes in oil composition were monitored using a gas liquid Chromatograph. Evaporation removed the largest quantity of material from the spill, the rate varying directly with the exposure time to solar radiation. Solution or sinking removed only minimal quantities of oil although the influence of these factors increased with time. The most notable physical change was the rapid formation of stable emulsions. These emulsions formed discrete lumps commonly referred to as “tarballs.” The formation of tarballs occurred within a few days after the spill and they remained stable over the four-month duration of the experiment. Their formation drastically reduced weathering effects by removing the bulk of the oil from contact with the air/seawater interface. It was concluded that a crude oil spill in the Arctic could contribute significantly to tarball pollution of northern oceans. Tarball formation is not limited, therefore, to warm waters and occurs independently of weathering processes. It would appear that tarball formation depends more on the chemical composition of the oil and the rate of formation depends upon the available wave mixing energy. The ultimate fate of oil spilled in Arctic regions could be in the form of persistent tarballs.

Why Sample? - Understanding Common Sampling Objectives for Oil Spill Response

2017 ◽  
Vol 2017 (1) ◽  
pp. 2561-2580
Author(s):  
Angeline Morrow ◽  
Christopher Pfeifer ◽  
Victoria Broje ◽  
Rachel Grunberg
Keyword(s):  
Decision Making ◽  
Oil Spill ◽  
Health And Safety ◽  
Chemical Properties ◽  
Alternative Response ◽  
Response Options ◽  
Worker Health And Safety ◽  
Oil Spill Response ◽  
Key Aspects ◽  
Physical And Chemical

ABSTRACT #2017-204: There is a growing recognition of the role science plays in supporting oil spill response coupled with increasing reliance on data-driven management and decision-making approaches. Collecting samples for analysis of hydrocarbons and other chemicals potentially used during oil spill response (e.g., dispersants) has become common place on many spills. While the rationale and approaches for oil spill sampling may be well known to experienced chemists and environmental scientists, the response community is still gaining experience in integrating sampling programs into dynamic oil spill response and decision-making. This paper reviews common sampling objectives for three key aspects of spill response: operational decision-support, environmental impact assessment (including natural resource damage assessment), and source identification. These broad categories span a range of interrelated sub-topics including, among others, public/worker health and safety; understanding how physical and chemical properties of oil influence selection of response options; monitoring cleanup effectiveness, especially for alternative response technologies such as dispersants; identifying and differentiating between spill and non-spill pollution sources; and evaluating potential impacts to resources at risk. Methods for achieving sampling objectives, including development of Sampling and Analysis Plans, are discussed with the goal of increasing awareness among response managers and improving response capability among staff who may be tasked with sampling support during training exercises or actual incidents. Relevant considerations for study design, collection methods, and analytical parameters are also reviewed.

Optimizing Offshore Combat of Oil Spills – Development of New Booms and Helicopter Based Application of Dispersants

2003 ◽  
Vol 2003 (1) ◽  
pp. 1279-1284
Author(s):  
Tharald M. Brekne ◽  
Sigmund Holmemo ◽  
Geir M. Skeie
Keyword(s):  
Oil Spill ◽  
Oil Spills ◽  
New Technology ◽  
Geographic Location ◽  
Chemical Dispersant ◽  
Offshore Installations ◽  
The Status ◽  
Oil Spill Response ◽  
Robust Systems ◽  
Norwegian Continental Shelf

ABSTRACT There is an increasing focus on offshore combat of oil spills on the Norwegian Continental Shelf (NCS). One result of this focus is a change from field specific to area specific contingency, moving from many medium sized oil spill combat vessels, to fewer and more robust systems and vessels. An important element in the emerging configuration is the use of helicopter based chemical dispersant systems, permanently located on offshore installations. An increasing diversity, of oil types being produced, configuration of installations, water depths and geographic location, are all factors that require a robust, mobile and flexible oil spill response. The Norwegian Clean Seas Association for Operating Companies (NOFO) has recently initiated development of new technology, as projects under NOFO's Research & Development Programme. Three of these projects address the development of improved heavy offshore booms, applying new principles for containment of oil, and a heavy duty skimmer optimized for mobility. A fourth project addresses the development of a system for helicopter based application of chemical dispersants, optimized for offshore storage and maintenance. This paper presents the status for and experience from these projects, as well as the plan for testing and verification of this new technology.

scholarly journals Microbial Functional Responses in Marine Biofilms Exposed to Deepwater Horizon Spill Contaminants

2021 ◽  
Vol 12 ◽  
Author(s):  
Rachel L. Mugge ◽  
Jennifer L. Salerno ◽  
Leila J. Hamdan
Keyword(s):  
Crude Oil ◽  
Oil Spill ◽  
Steel Structures ◽  
Functional Redundancy ◽  
Mitigation Strategies ◽  
Source Water ◽  
Functional Responses ◽  
Chemical Dispersant ◽  
Marine Biofilms ◽  
And Function

Marine biofilms are essential biological components that transform built structures into artificial reefs. Anthropogenic contaminants released into the marine environment, such as crude oil and chemical dispersant from an oil spill, may disrupt the diversity and function of these foundational biofilms. To investigate the response of marine biofilm microbiomes from distinct environments to contaminants and to address microbial functional response, biofilm metagenomes were analyzed from two short-term microcosms, one using surface seawater (SSW) and the other using deep seawater (DSW). Following exposure to crude oil, chemical dispersant, and dispersed oil, taxonomically distinct communities were observed between microcosms from different source water challenged with the same contaminants and higher Shannon diversity was observed in SSW metagenomes. Marinobacter, Colwellia, Marinomonas, and Pseudoalteromonas phylotypes contributed to driving community differences between SSW and DSW. SSW metagenomes were dominated by Rhodobacteraceae, known biofilm-formers, and DSW metagenomes had the highest abundance of Marinobacter, associated with hydrocarbon degradation and biofilm formation. Association of source water metadata with treatment groups revealed that control biofilms (no contaminant) harbor the highest percentage of significant KEGG orthologs (KOs). While 70% functional similarity was observed among all metagenomes from both experiments, functional differences between SSW and DSW metagenomes were driven primarily by membrane transport KOs, while functional similarities were attributed to translation and signaling and cellular process KOs. Oil and dispersant metagenomes were 90% similar to each other in their respective experiments, which provides evidence of functional redundancy in these microbiomes. When interrogating microbial functional redundancy, it is crucial to consider how composition and function evolve in tandem when assessing functional responses to changing environmental conditions within marine biofilms. This study may have implications for future oil spill mitigation strategies at the surface and at depth and also provides information about the microbiome functional responses of biofilms on steel structures in the marine built environment.

The Minerals Management Service Cutting-Edge Oil Spill Response Research

1999 ◽  
Vol 1999 (1) ◽  
pp. 1167-1169
Author(s):  
Joseph V. Mullin
Keyword(s):  
Oil Spill ◽  
Oil Spills ◽  
Chemical Properties ◽  
Test Facility ◽  
Management Service ◽  
Joint Research ◽  
Public And Private ◽  
Oil Spill Response ◽  
Equipment Testing ◽  
Physical And Chemical

ABSTRACT The Minerals Management Service (MMS), is the principal U.S. government agency funding offshore oil spill response research. The MMS, a bureau of the Department of the Interior, maintains a comprehensive Oil Spill Response Research program in support of oil spill prevention and response. Through funding provided by MMS, scientists and engineers from the public and private sectors worldwide are working to address outstanding gaps in information and technology concerning the cleanup of oil spills. Joint research projects with Environment Canada (EC) continue to focus on determining the physical and chemical properties of crude oil, the fate and behavior of spilled oil, remote sensing and mapping of oil slicks, chemical treating agents including dispersants, and innovative shoreline cleanup strategies. In joint projects with the National Institute of Standards and Technology (NIST), MMS continues to assess the capabilities of in situ burning as an oil spill response tool. Also discussed is OHMSETT, the national Oil Spill Response Test Facility. OHMSETT is the only facility in the world where government agencies, universities, and private companies can conduct full-scale oil spill response equipment testing, research, and training with oil under controlled conditions.

scholarly journals Review of the Science behind Oil Spill Fate Models: Are Updates Needed?

2021 ◽  
Vol 2021 (1) ◽  
Author(s):  
Lin Zhao ◽  
Timothy Nedwed ◽  
Douglas Mitchell
Keyword(s):  
Oil Spill ◽  
Particle Tracking ◽  
Chemical Properties ◽  
Transport Processes ◽  
Future Research ◽  
Near Surface ◽  
Oil Transport ◽  
Oil Spill Response ◽  
Planning Processes ◽  
Physical And Chemical

Abstract Oil spill models play an important role in the oil spill response decision making and contingency planning processes. The current generation of spill models mostly use Lagrangian based particle tracking random walk methods for oil transport processes combined with individual algorithms for oil fate processes (Spaulding, 2017). The fate of near surface oil movement is modeled using algorithms describing oil spreading, evaporation, emulsification, entrainment, dissolution, and biodegradation. These fate processes are applied to oil in the Lagrangian particle tracking elements to alter the physical and chemical properties of the oil, and subsequently the oil behavior. In this paper, we review the major algorithms used in oil spill models and identify the science and physics underpinning them. For each, we evaluated how far the science has advanced since the algorithms were developed to identify those that could be upgraded based on current understanding. We also identified algorithms where future research is needed because the physical and chemical behaviors are not fully understood. These areas include the spreading behavior of surface slicks, surface-slick emulsification, and the physical transport of small oil droplets near the air-water interface.

Occupational-health Aspects of Marine Oil-spill Response

1999 ◽  
Vol 71 (1) ◽  
pp. 113-133 ◽  
Author(s):  
John M. Park ◽  
Michael G. Holliday
Keyword(s):  
Occupational Health ◽  
Crude Oil ◽  
Oil Spill ◽  
Health And Safety ◽  
American Petroleum Institute ◽  
Past Century ◽  
Oil Well ◽  
Marine Oil ◽  
Oil Spill Response ◽  
Mammalian Toxicity

Introduction: This chapter addresses chemical aspects of occupational health and marine oil-spill response and is restricted to exposures to crude oil in its various forms. Thus in-situ burning of oil is included, but ancillary chemicals such as surfactants or bioremediation agents are not. The content of this chapter is largely based on the literature published after 1985, the date of a comprehensive review conducted by Politzer et al. [1985] for the American Petroleum Institute, and on a review carried out for the Marine Spill Response Corporation early in 1993 [Holliday and Park, 1993].Concern about health and safety is a normal part of every oil spill. In general, safety is easier to understand and address than are concerns about exposure to crude oil and other chemicals which might be used in the response. At one level, human exposure can be addressed through the enforcement of very conservative requirements for the use of personal protective equipment (PPE). In the real world, however, conditions at a spill site make the use of such equipment inconvenient or even hazardous, and so the goal becomes to balance the risk from exposure with the appropriate level of PPE.While oil-spill cleanup is a comparatively new aspect of occupational-health practice, and dates from the formalization of response measures by companies and national and international agencies (something that occurred over the last 30 years), exposure to crude oil itself is a "mature" occupational-health matter. Workers have been exposed, both by inhalation and dermally, to the effects of crude oil for the past century. The exposure of response workers during the early phases of the oil-spill response can be likened to that experienced by oil-well-drilling crews and, to a lesser extent, by oil-well-maintenance personnel or fighters of oil-well fires. In contrast, exposures in the later stages of the cleanup are less clearly related to occupations within the oil industry. The crude oil will have been altered by weathering, and exposure to cleanup chemicals (e.g., dispersants, bioremediation agents) will become relatively more prominent. Such substances are beyond the scope of this chapter, and in any event, few data are available on the compositions or mammalian toxicity of dispersants. Although there are frequent references to toxicity in connection with dispersants, these invariably seem to refer to ecotoxicity. Human hazard does not appear to be an issue. For example, in a recently published paper entitled, "Effectiveness and safety of biosurfactants as agents of oil spill response" [Lepo et al., 1997], "safety" refers to possible toxicity to crustaceans and fish.

Workers Safety & Health During Iguassu Oil Spill Response Oil Spill in Iguassu River – Araucaria, Parana, Brazil

2003 ◽  
Vol 2003 (1) ◽  
pp. 1115-1123
Author(s):  
Alexandre Glitz
Keyword(s):  
Crude Oil ◽  
Oil Spill ◽  
Oil Recovery ◽  
Health Concerns ◽  
Sunday Afternoon ◽  
Safety And Health ◽  
Rivers And Streams ◽  
Oil Spill Response ◽  
Spilled Oil ◽  
Hydrocarbon Vapor

ABSTRACT On July 16, 2000 a major oil spill occurred at the side of the Araucaria refinery. A total of 4,000 m3 of a light crude oil run down around two kilometers trough Saldanha creek, crossing and contaminating four wetlands. The oil discharged into Barigüi River, a tributary of Iguassu River contaminating 6 kilometers in Barigüi River and 60 in Iguassu River. An oil recovery and cleanup operation was mounted. Almost 3000 workers were hired in haste to clean and recover oil in the impacted wetlands area, as well as in the water streams. The accident happened on a Sunday afternoon, during one of the coldest (for Brazilian standards) winters in past years, with temperatures as low as − 6°C. At the start of the oil recovery work, a very important issue was worker's safety and health. Most of the workers were unskilled people, unemployed until the accident and among them a great number of illiterate persons. The paper describes the issues with regards to safety and health, the actions taken to protect worker's health during manual oil recovery in wetlands, the means used to reduce hydrocarbon vapor exposure and evaluation of worker's exposure to hydrocarbon vapors. The effort was successful, in nine days all the free oil was removed from the rivers. The cleaning of the riverbanks and inundation areas was completed in three months. The creek and wetland areas ascending Barigüi River held around 70 per cent of the spilled oil. In these areas the safety and health concerns where higher. All superficial oil was removed from the rivers and streams.

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