Shell Development Company Research Articles

Globalisation and Transnational Corporations in the Petroleum Sector of the Nigerian Economy: A Historical Analysis

The crucial ingredient in the development of the global economy or any economy for that matter is an investment. Transnational Corporations (TNCs) are the main purveyors of Foreign Direct Investment (FDI). The Nigerian situation is no exception to the above pattern where TNCs occupies a towering influence over strategic sectors of the economy, especially the Petroleum sector. This paper examines the nature, dynamics, and scope of the operations of Transnational Corporations such as the Anglo/Dutch Shell Development Company in Nigeria’s oil sector. The positive and negative impacts of such corporations on the Nigerian economy are also highlighted and weighed. It also analyses why the Nigerian state has found it more difficult to control the activities of such corporations. The research method adopted for the study is a historical approach that took cognisance of existing scholarly works and the use of simple descriptive analysis of available data on the study. The paper concluded by submitting that the corporations benefited more from the Nigerian economy than whatever they might have contributed, while certain suggestions are also proffered as a way forward.

The price of oil.

Political tensions in the Middle East once again remind us of the fragile dependency of the Western nations on imported petroleum, which have driven the price of a barrel of crude oil to above $100, as was the case prior to the world economic crash in 2008. British motorists and owners of haulage companies flinch nervously in the face of rising prices at the pumps for fuel, feared to reach 2.00 [pounds sterling]/litre if events fail to calm down, since supplies of crude oil from Libya, already cut by 500,000 barrels per day from 1.6 million barrels per day, may fall to zero, leading to shortages and further hikes in oil and consequently fuel prices. Saudi Arabia have promised to make-up the difference by pumping out more but there is doubt as to whether they have in fact sufficient spare capacity to do so, certainly not the light crude which is exported to Europe for refining into petrol. There is, for that matter, some controversy over how much oil the kingdom does have in its reserves in total, which are thought might be far less than is claimed (1). The latter aspect is critical to the timing of a phenomenon (2) proposed as long ago as 1956 by Dr M. King Hubbert, a petroleum geologist working for the Shell Development Company. Hubbert's predictions were made for the lower-48 states of America, that US oil production would peak in either 1965 or 1970, depending on the volume of the reserve that he estimated, i.e. the total amount of oil that would ultimately be recovered given prevailing technology and oil-prices. Western civilisation has been built literally on sand--underpinned by the desert sands under which most of the petroleum lies. Our position is thus precarious, resting upon an ability to import ever greater quantities of crude to furnish economic and material growth. In the case of the lower-48 US fields, oil production did indeed peak in 1970, as Hubbert predicted, and by application of similar reasoning the peak in world oil production can be expected to occur close to the present time. The CEO of Shell has stated that the world will be unable to meet its demand for oil by 2015, while other commentators think so as early as 2012. Most of the major oil companies are investing in deep-drilling technologies to recover oil from less accessible regions of the Earth, including the Arctic, and it is likely that there will be further accidents such as occurred in the Gulf of Mexico, as new technologies and regions are developed to advance the map of as yet uncharted territory from which to slake our thirst for oil. Not everyone agrees with Hubbert, and yet the USA, once the world's leading oil-exporting nation now imports 2/3 of the oil that it uses; a substantial proportion coming from the Middle East. It is argued that the Hubbert-peak, beyond which supplies of crude oil can be expected to fall forever, is an oversimplification; that it does not take account of new discoveries of or of the exploitation of unconventional oil. In the former regard, world occurred around 1965 and there have been no giant fields (i.e. those containing proved recoverable reserves of 500 million barrels or more) found since the early 1980s. Indeed, the global consumption of crude oil has exceeded the discovery of new quantities of it since the mid-1980s. Since Hubbert identified (2) a 40 year lag between peak discovery and peak production, this would also suggest that we are close to the point of peak or have even passed it. Oil production is somewhat confounded by the reference to liquids rather than oil, which includes hydrocarbons that are recovered, sometimes in great quantity, from natural gas wells, which condense from the gas in liquid form once the pressure drops below the dew-point. The latter are also called condensates, and to their volume may be added natural gas liquids, hydrocarbons that exist in fields as constituents of natural gas but which are recovered separately as liquids, including propane, butane, pentane, hexane and heptane, but not methane and ethane, since these hydrocarbons need refrigeration to be liquefied. …

Reevaluating Hubbert's prediction of U.S. peak oil

In 1956, M. King Hubbert, chief consultant for the Shell Development Company's exploration and production research division, forecasted that U.S. oil production would peak in the early 1970s. He subsequently updated this prediction using newer data, but the predicted timing of peaking did not change significantly (see Hubbert [1982] for a review and references to earlier papers). In 1971, U.S. annual production of crude oil peaked at slightly more than three billion barrels (bbl).Yet, Hubbert's model continues to be challenged by some. For instance, according to economist Michael Lynch, president of Strategic Energy and Economic Research, Inc., Winchester, Mass., it was only after Hubbert published his predictions “that the Hubbert curve came to be seen as explanatory in and of itself, that is, geology requires that production should follow such a curve” [Lynch,2003].

The problem of too much power in detecting biases for a real chemical process

Statistical hypothesis testing in a strategic fashion is often used to locate biased process variables and nodes (interconnecting points) with material leaks. Power, which increases with the number of measurements used in a hypothesis test, represents the ability of the test to correctly conclude the existence of bias or a leak. As computer technology continues to improve, so does the ability to store large quantities of data. Measurement bias occurs from miscalibrated instruments and equipment failures. To some degree, most instruments will have some amount of bias at any given time. Thus, with huge data sets, statistical hypothesis testing strategies will flag nearly all instruments as being biased, which is not a practical result when one is only interested in a bias above a certain threshold (i.e., control of power). This work demonstrates the dilemma of too much power and stresses the control of power by using power functions and a controlled number of measurements. This study was conducted using real plant data provided by the Shell Development Company.

An Efficient Synthetic Route to Ethyl 2-Aryl-4-hydroxy-1,3(2H,4H)- dioxoisoquinoline-4-carboxylates(1).

ADVERTISEMENT RETURN TO ISSUEPREVNoteNEXTAn Efficient Synthetic Route to Ethyl 2-Aryl-4-hydroxy-1,3(2H,4H)- dioxoisoquinoline-4-carboxylates1J. Edward Semple, Robert M. Rydzewski, and Gary GardnerView Author Information Shell Development Company, Biological Sciences Research Center, P.O. Box 4248, Modesto, California 95352, and Du Pont Agricultural Products, Stine-Haskell Research Center, P.O. Box 30, Newark, Delaware 19711 Cite this: J. Org. Chem. 1996, 61, 22, 7967–7972Publication Date (Web):November 1, 1996Publication History Received14 June 1996Published online1 November 1996Published inissue 1 January 1996https://doi.org/10.1021/jo961135jCopyright © 1996 American Chemical SocietyRIGHTS & PERMISSIONSArticle Views537Altmetric-Citations20LEARN ABOUT THESE METRICSArticle Views are the COUNTER-compliant sum of full text article downloads since November 2008 (both PDF and HTML) across all institutions and individuals. These metrics are regularly updated to reflect usage leading up to the last few days.Citations are the number of other articles citing this article, calculated by Crossref and updated daily. Find more information about Crossref citation counts.The Altmetric Attention Score is a quantitative measure of the attention that a research article has received online. Clicking on the donut icon will load a page at altmetric.com with additional details about the score and the social media presence for the given article. Find more information on the Altmetric Attention Score and how the score is calculated. Share Add toView InAdd Full Text with ReferenceAdd Description ExportRISCitationCitation and abstractCitation and referencesMore Options Share onFacebookTwitterWechatLinked InReddit Read OnlinePDF (199 KB) Get e-AlertsSUBJECTS:Enolates,Ethyl groups,Inhibitors,Organic compounds,Reaction products Get e-Alerts

Biodegradation of hazardous wastes.

Biological treatment of hazardous wastes has the potential for effective, practical, and economical remediation of some Superfund sites and other hazardous waste problems. Some biological hazardous waste treatments may also be applicable for preventing the occurrence of future hazardous waste sites. From a public health perspective, this technology may allow for the treatment of environmental hazardous wastes such that potential human health effects are ameliorated, or indeed prevented, specifically by reducing the amount and toxicity of hazardous substances. Considering the importance of the environmental concerns associated with hazardous wastes, specifically from a public health perspective, a conference on the Biodegradation of Hazardous Wastes was held April 9-10, 1990, at Utah State University. The main purpose of the meeting, and the focus of this report, was to provide an up-to-date review of some of the biological degradation research currently available and undergoing development and to provide a forum to discuss this technology's impact on human health and the environment. In addition, current and future use of biological treatment technologies were discussed, primarily from the perspective of technology transfer; and research needs and opportunities were identified. The meeting was chaired by S. Aust, Director of the Biotechnology Center at Utah State University, and the conference was organized by a committee consisting of Aust, A. Bourquin (ECOVA), J. Fouts (NIEHS), J. Loper (University of Cincinnati), J. Salanitro (Shell Development Company), W. Suk (NIEHS), and J. Tiedje (Michigan State University). The conference brought together investigators in the fields of enzymology, microbiology, and molecular biology of hazardouswaste-degrading organisms, which included bacterial, fungal, and plant species. In addition, toxicological evaluation of biodegradation processes was discussed, essentially from the viewpoint of the agents under investigation, which consisted of the hydrocarbons, polychlorinated biphenyls (PCB), polycyclic aromatic hydrocarbons (PAH), volatile organics and chloroorganics, and benzene, toluene, ethyl benzene, and xylene (BTEX). Integrated within the context of the conference were presentations on the development of pertinent engineered systems and their applications in the field. The conference documented the potential for biological degradation of hazardous wastes and clearly reflected the many recent advances and discoveries that have been made in this rapidly moving field. Several presentations documented the metabolism of chemicals previously regarded as resistant to biodegradation, for example, bacterial systems that oxidize trichloroethylene (TCE) or dehalogenate PCB. This was perhaps the overall theme of the meeting, for at one point biodegradation of hazardous organic chemicals was described in terms of a continuum in which easily degraded organics, such as BTEX, appeared on the left, and inordinately recalcitrant compounds, such as PCB, appeared on the right. On the left are those chemicals currently thought to be amenable to degradation, and on the right are those chemicals that have not been shown to be degraded. The consensus reached during discussion periods was that continuing discoveries and development of microorganisms, and new investigations into the mechanisms of biodegradation, are combining to reduce the number and type of hard-to-degrade chemicals. This in turn means that we can more easily degrade hazardous wastes. However, it was noted that biological treatability studies will require a complete understanding of the fate and transport of contaminants and the pathway used by the organisms to degrade the chemicals. Nonetheless, there was confidence that basic research would contribute significantly toward the development of this knowledge. A panel discussion at the conclusion of the meeting noted the significant advances in the field and detailed future research needs, the strengths and weaknesses of current knowledge, and 'Biotechnology Center, Utah State University, Logan, UT 84322-4705. 2ECOVA, Corporate Office, 3820 159th Avenue, NE, Redmond, WA 98052. 'Department of Molecular Genetics, Biochemistry and Microbiology, University of Cincinnati, 231 Bethesda Avenue, Cincinnati, OH 45267-0524. 4Shell Development Company, Westhollow Research Center, P.O. Box 1380, Houston, TX 77251-1380. 5National Institute of Environmental Health Sciences, PO. Box 12233, Research Triangle Park, NC 27709. 6Crop and Soil Science, 540 E Plant Soil Science Building, Michigan State University, East Lansing, MI 48824. Address reprint requests to W. A. Suk, National Institute of Environmental Health Sciences, P.O. Box 12233, Research Triangle Park, NC 27709. This paper was presented at the International Biostatistics Conference in the Study of Toxicology that was held May 13-25, 1991, in Tokyo, Japan.

Shell Development Company

Shell Development Company

Viscoelastic Behavior, Thermodynamic Compatibility, and Phase Equilibria in Block Copolymer-Based Pressure-Sensitive Adhesives

Abstract The viscoelastic behavior, thermodynamic compatibility, and phase equilibria in block copolymer-based pressure-sensitive adhesives were investigated. The block copolymers investigated were: (1) polystyrene-block-polybutadiene-block-polystyrene (SBS) copolymer (KRATON® D-1102, Shell Development Company) and (2) polystyrene-block-polyisoprene-block-polystyrene (SIS) copolymer (KRATON® D-1107, Shell Development Company). The tackifying resins investigated were: (1) WINGTACK® 86 (Goodyear Tire & Rubber Company) and (2) PICCOTAC® 95BHT (Hercules Inc.). Samples of various compositions were prepared by a solution-casting method with toluene as solvent. Measurements of dynamic storage modulus (G″), dynamic loss modulus (G″), and loss tangent (tan δ) were taken, using a Rheometrics Mechanical Spectrometer. It was found that: (1) both WINGTACK 86 and PICCOTAC 95BHT were equally effective in decreasing the plateau modulus (G O N ), and increasing the glass transition temperature (Tg ) of the polyisoprene mi...

Viscoelastic behavior and order‐disorder transition in mixtures of a block copolymer and a midblock‐associating resin

AbstractThe viscoelastic behavior and order‐disorder transition in mixtures of a block copolymer and a midblock‐associating resin were investigated. The block copolymers investigated were polystyrene‐block‐polysioprene‐block‐polystyrene (SIS) copolymers (Shell Development Company), specifically Kraton D‐1107, with the block molecular weights 10,000S‐120,000I‐10,000S, and Kraton D‐1111, with the block molecular weights 15,000S‐100,000I‐15,000S. The midblock‐associating resin investigated was a resin polymerized from C5 hydrocarbon, referred to as Piccotac 95BHT (Hercules Inc.), which is an aliphatic hydrocarbon containing considerable amounts of cyclic structures, with a weight‐average molecular weight of 1,100 and a glass transition temperature Tg of 43°C. In the investigation, mixtures of the block copolymer and Piccotac 95BHT were prepared with toluene as solvent. Temperature scans of the samples were made to obtain information on dynamic storage modulus G′, dynamic loss modulus G″, and loss tangent tan δ, using a Rheometrics dynamic mechanical spectrometer. It was found that Piccotac 95BHT decreased the plateau modulus G0N and increased the Tg of the polyisoprene midblock of the SIS block copolymer in the mixture. This experimental observation led to the conclusion that Piccotac 95BHT associates (or is compatible) with the rubbery polyisoprene midblock of the SIS block copolymer. The order‐disorder transition behavior of mixtures of SIS block copolymer and Piccotac 95BHT was also investigated by a rheological technique proposed by Han and Kim (Ref. 21). The order‐disorder transition temperature Tr (i.e., the temperature at which the ordered microdomain structure of the block copolymer completely disappears) of the SIS block copolymer decreased steadily with increasing amount of Piccotac 95BHT in the mixture. With the information determined on Tr, a phase diagram for the mixture was constructed, showing the boundary between the mesophase and homogeneous phase in the mixture. The phase diagram is in qualitative agreement with the theoretical predictions of Whitmore and Noolandi (Ref. 28).

Rheological technique for determining the order–disorder transition of block copolymers

AbstractA rheological technique is proposed for determining the thermally induced order–disorder transition of block copolymers. In the present investigation, a cone‐and‐plate rheometer was used to measure dynamic storage and loss moduli, G′(ω) and G″(ω), as a function of angular frequency ω of a commercial grade polystyrene‐block‐polyisoprene‐block‐polystyrene (SIS) tri‐block copolymer (KRATON D‐1107, Shell Development Company) in the temperature range from 140 to 240°C. For comparison purposes, dynamic viscoelastic properties of a commercial grade low‐density polyethylene (LDPE) were also determined in the temperature range from 160 to 238°C. We have found that log G′ versus log G″ plots for the LDPE show no temperature dependence, whereas log G′ versus log G″ plots for the SIS block copolymer do show systematic temperature dependence in the temperature range 140–230°C. This observation leads us to conclude that the order–disorder transition of the SIS block copolymer takes place gradually as the temperature is raised from 140 to 230°C. This conclusion is in good agreement with that drawn from the study of Roe (Ref. 33), who employed the same block copolymer using small‐angle x‐ray scattering. It is not possible to reach such a conclusion using log G′(ω) versus log ω, log G″(ω) versus log ω, or log η′(ω) versus log ω plots in which η′ is the dynamic viscosity. We have demonstrated further that the use of frequency‐temperature superposition is inappropriate for investigating the rheological behavior of block copolymer in the temperature range over which a thermally induced transition from an ordered structure to a disordered homogeneous phase occurs. We therefore suggest that when using information on dynamic viscoelastic properties, log G′ versus log G″ plots be used for determining the thermally induced order–disorder transition of block copolymers.

Optimum detergency conditions with nonionic surfactants: I. Ternary water-surfactant-hydrocarbon systems

Enhanced videomicroscopy was used to observe the dynamic behavior that occurred when pure straight-chain hydrocarbons were contacted with pure nonionic surfactant-water mixtures at various temperatures. Detergency experiments at Shell Development Company determined the ability of the same surfactants to remove the same oils from small fabric samples. For a given system maximum rates of both oil solubilization (from videomicroscopy) and oil removal (from detergency) occurred near the phase inversion temperature (PIT). In these systems, the PIT was well above the surfactant cloud point and, in most cases, in the temperature range where the surfactant-water mixture contained lamellar liquid crystal. The detergency mechanism under these conditions appears not to be rollback but some combination of solubilization and emulsification.

An automated pneumatic transfer system for oxygen determinations by neutron activation analysis

This report describes a newly installed automated sample transfer and data acquisition and analysis system for oxygen determinations by neutron activation analysis. Oxygen is an important element for oil products research. The laboratory at the Westhollow Research Center of the Shell Development Company performs about 1600 oxygen determinations per year.

Theory of induced‐polarization logging in a borehole

Currently, there is interest by the petroleum well‐logging industry in the potential use of induced polarization (IP) measurements to improve formation evaluation in shaly sands. Shell Development Company has constructed an experimental four‐electrode IP and resistivity logging tool to obtain downhole measurements in shaly sands. This study contributes to the theoretical understanding and interpretation of the dynamic (i.e., time‐dependent) response of this type of downhole IP logging device. A low‐frequency (e.g., 32 Hz or less) electric current oscillating at a single fixed frequency is applied between a pair of current electrodes in a borehole. The resulting voltages induced between pairs of potential measuring electrodes in the borehole are calculated by solving the time‐dependent Maxwell’s equations. Inductive electromagnetic (EM) coupling contributions to apparent (e.g., measured) IP phase angles are automatically taken into account. The model is applied to the study of normal logging arrays for which the voltage measuring electrodes are interior to the current electrodes. The model responses are calculated for normal arrays in both infinitely thick noninvaded formations and infinitely thick invaded formations. EM coupling contributions to apparent IP phase angles have an approximately universal dependence on a scaling parameter defined here. The scaling relationship permits the quantitative estimate of EM coupling effects for specific tool parameters (i.e., electrode spacings and frequencies) and formation characteristics (i.e., apparent conductivities). Therefore, scaling relationships of this type should be useful in the design of IP tools. An inverse method, developed for determining true formation IP phase angles and resistivities from apparent values measured by an IP tool, utilizes data from multiple pairs of voltage‐measuring electrodes and exploits the fact that, for the systems of interest, the inverse resistivity and IP problems can be “decoupled.” The assumption that IP phase angles have a logarithmic dependence on frequency over a decade frequency interval leads to a nonlinear relationship between percent frequency effect (PFE) and IP phase angle. This nonlinear relationship agrees well with experimental data.

An Improved Successive Linear Programming Algorithm

Successive Linear Programming (SLP) algorithms solve nonlinear optimization problems via a sequence of linear programs. They have been widely used, particularly in the oil and chemical industries, beginning with their introduction by Griffith and Stewart of Shell Development Company in 1961. Since then, several applications and variants of SLP have appeared, the most recent being the SLPR algorithm described in this journal in 1982 (Palacios-Gomez et al.). SLP procedures are attractive because they are fairly easy to implement if an efficient, flexible LP code is available, can solve nonseparable as well as separable problems, can be applied to as large a problem as the LP code can handle (often thousands of constraints and variables), and have been successful in many practical applications. This paper describes a new SLP algorithm called PSLP (Penalty SLP). PSLP represents a significant strengthening and refinement of the SLPR procedure described in Palacios-Gomez et al. (Palacios-Gomez, F., L. Lasdon, M. Engquist. 1982. Nonlinear optimization by successive linear programming. Management Sci. 28 1106–1120.). We give a convergence proof for PSLP—the first SLP convergence proof for nonlinearly constrained problems of general form. This theory is supported by computational performance—in our tests, PSLP is significantly more robust than SLPR, and at least as efficient. A Fortran computer implementation is described. A simplified version of PSLP has already solved several “real world” NLP problems at Exxon (Baker and Lasdon [Baker, T. E., L. S. Lasdon. 1985. Successive linear programming at Exxon. Management Sci. 31 (March) 264–274.), including nonlinear refinery models of up to 1000 rows. As with other SLP algorithms, PSLP is especially efficient on problems which are highly constrained, i.e., which have nearly as many active constraints as there are variables. For problems with vertex optima (at least as many active constraints as variables), it is quadratically convergent. Nonlinear refinery models often have vertex optima, since they are large and mostly linear, and on line process unit optimization problems are likely to possess highly constrained solutions as well. PSLP has great potential for accurate, efficient solution of such problems.

Petrophysical parameters estimated from visual descriptions of carbonate rocks: A field classification of carbonate pore space : Lucia, F J J Pet Technol, V35, N3, March 1983, P629–637

This paper describes the basic geologic parameters which control the petrophysical parameters and show how they are related. The results presented are based on a large volume of data produced in Shell Development Company and Shell Oil Company on the origin of carbonate pore space and the relationships between petrophysical and geological parameters. A classification of carbonate porosity is proposed based on the data presented. This classification is intended to be used in the field or for routine laboratory description. 5 refs.

OPEN OCEAN SKIMMER PERFORMANCE TESTS*

ABSTRACT An oil skimmer was tested in a controlled crude oil dumping off the New Jersey Coast in early 1980. The program was sponsored by the U.S. Navy (USN), Director of Ocean Engineering, Supervisor of Salvage through the Oil and Hazardous Materials Simulated Environmental Test Tank (OHMSETT) Interagency Technical Committee comprised of the U.S. Environmental Protection Agency (EPA), U.S. Coast Guard (USCG), U.S. Geological Survey (USGS), USN, and Environment Canada. The tests were designed to evaluate the Spilled Oil Containment Kit (SOCK) developed by Shell Development Company. The skimmer had been designed as a physical attachment to an oil industry work boat in a vessel of opportunity deployment mode. The USNS Powhatan T-ATF fleet tug as chosen as a similar vessel and one that had an oil spill recovery operations mode. The test program is described including the oil/water distribution and collection system, deployment and retrieval of the SOCK, the onboard fluid measurement, data analysis, logistics, weather and environment measurements, and the Powhatan/SOCK interface. The light crude oil and ocean water collected were stored aboard the vessel, decanted, and the emulsified oil later sold as waste oil. Eight experimental crude oil dumps are described and analyzed. The sea conditions varied from calm to 1.8-meter significant heights. During the 6 days at sea, 50 cubic meters of oil were dumped and the skimmer collected 32 cubic meters of oil. The program is analyzed for suggestions to future open ocean testing plans incorporating oil skimmers with and without vessels of opportunity. This program was fortunate in having available a skimmer that had extensive testing as a model, seaworthiness testing on commercial work boats, and oil-collecting experience in a spill of opportunity.

Thermodynamic interpretation of solute‐polymers interactions at infinite dilution

Journal of Applied Polymer ScienceVolume 23, Issue 9 p. 2825-2825 ErratumFree Access Thermodynamic interpretation of solute-polymers interactions at infinite dilution K. A. Karim, K. A. Karim Gulf Oil Chemicals Company, Houston, Texas 77079Search for more papers by this authorD. C. Bonner, D. C. Bonner Chemical Engineering Department, Shell Development Company, Houston Texas 77001Search for more papers by this author K. A. Karim, K. A. Karim Gulf Oil Chemicals Company, Houston, Texas 77079Search for more papers by this authorD. C. Bonner, D. C. Bonner Chemical Engineering Department, Shell Development Company, Houston Texas 77001Search for more papers by this author First published: 1 May 1979 https://doi.org/10.1002/app.1979.070230929Citations: 2AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL No abstract is available for this article.Citing Literature Volume23, Issue91 May 1979Pages 2825-2825 RelatedInformation

Ocean current meeting proceedings available

Proceedings of the Current Measurement Working Conference, a 3‐day meeting of 150 marine specialists, are available from the Sea Grant Office at the University of Delaware. The first two days of the meeting were devoted to presentations by invited speakers describing activities in scientific research, ocean engineering, environmental impact assessment, operational surveys, and current measurement system testing and development. Among the participants were Nicholas Fofonoff, Woods Hole Oceanographic Institution; George Z. Forristall, Shell Development Company; J . Dungan Smith, University of Washington; Paul Teleki, U.S. Geological Survey; and David Halpern, NOAA/Pacific Marine Environment Laboratory.An ad hoc group was formed at the meeting to investigate the possibility of creating a permanent committee on procedures and standards affiliated with an appropriate professional society.

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HIGH CURRENT CONTROL OF FLOATING OIL

ABSTRACT In high current oil spill cleanup operations, containment devices should be used as one element in a containment-pickup system. To achieve successful control over the oil slick, three activities have been identified based on an analysis of the present hydrodynamic theory of oil spill containment:absorb or convert the kinetic energy of the fast-flowing water streamseparate the oil film from as much of the free-flowing stream as possibledirect the oil film to a controlled area to facilitate its collection and removal. Acting under the authority of the Federal Water Pollution Control Act Amendments of 1972, the Environmental Protection Agency awarded a contract to Ultrasystems, Inc., of Newport Beach, California, to design, develop, and demonstrate a streamlined boom utilizing hydrofoil concepts. Additionally, EPA awarded a contract to the Shell Development Company to develop an unconventional boom profile utilizing a perforated incline plate as a baffle upstream of a conventional plate boom. This baffle creates a flow-sheltered region where the oil layer can thicken, thus facilitating its removal. Following developmental tests of these concepts, full-scale prototype tests will be conducted at the Environmental Protection Agency's OHMSETT facility in Leonardo, New Jersey. Following these tests, final reports will be issued which will include recommended design, fabrication, and material specifications.