Diagnostics Plan for the National Compact Stellarator Experiment

Johnson, D. W.; Brown, Thomas G.; Neilson, H.; Schilling, G.; Takahashi, H.; Zarnstorff, M. C.; Cole, M. J.; Lazarus, E. A.; Fenstermacher,

doi:10.2172/808317

Cited by 6 publications

(8 citation statements)

References 1 publication

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“…Similarly, the other sample characteristics including elemental N and S, sand/silt/clay content, and total extractable hydrocarbons showed no strong correlation with the F values for the individual PAHs, and r 2 values were nearly all under 0.4. This lack of predictive capabilities using common soil parameters is in agreement with recent reports showing that knowledge of simple soil parameters (such as organic carbon) is not sufficient to predict the bioavailability of organic pollutants (5,14,16,(28)(29)(30)(31)(32)(33)(34)(35)(36)(37)(38)(39).…”

Section: Resultssupporting

confidence: 89%

“…In addition, the molar C/H ratios for the CG samples (0.6- 1.1, except for CG-11 which is 2.3, but also contained particles that looked like coal) correspond much better with the five natural sediments and soils (0.6-0.8) than to the much higher ratios for the OG samples (2.4-6.3). Similarly, CG sample molar C/N ratios (22)(23)(24)(25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36)(37)(38)(39)(40)(41) and the five natural soils and sediments (15)(16)(17)(18)(19)(20)(21)(22)(23)(24)(25) are substantially lower than those of the OG samples (78-93). Taken together, these analyses indicate that the aromatic nature of the carbon in the OG samples is much higher than for the CG samples and support the OG and CG carbon structures proposed earlier by others (3,40).…”

Section: Effect Of Pah and Matrix Organic Composition Onmentioning

confidence: 92%

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Comparing PAH Availability from Manufactured Gas Plant Soils and Sediments with Chemical and Biological Tests. 1. PAH Release during Water Desorption and Supercritical Carbon Dioxide Extraction

Hawthorne

Poppendieck

Grabanski

et al. 2002

Environ. Sci. Technol.

120

132

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Soil and sediment samples from oil gas (OG) and coal gas (CG) manufactured gas plant (MGP) sites were selected to represent a range of PAH concentrations (150-40,000 mg/kg) and sample matrix compositions. Samples varied from vegetated soils to lampblack soot and had carbon contents from 3 to 87 wt %. SFE desorption (120 min) and water/XAD2 desorption (120 days) curves were determined and fit with a simple two-site model to determine the rapid-released fraction (F) for PAHs ranging from naphthalene to benzo[ghi]perylene. F values varied greatly among the samples, from ca. 10% to >90% for the two- and three-ring PAHs and from <1% to ca. 50% for the five- and six-ring PAHs. Release rates did not correlate with sample matrix characteristics including PAH concentrations, elemental composition (C, H, N, S), or "hard" and "softs" organic carbon, indicating that PAH release cannot easily be estimated on the basis of sample matrix composition. Fvalues for CG site samples obtained with SFE and water desorption agreed well (linear correlation coefficient, r2 = 0.87, slope = 0.93), but SFE yielded higher F values for the OG samples. These behaviors were attributed to the stronger ability of carbon dioxide than water to desorb PAHs from the highly aromatic (hard) carbon of the OG matrixes, while carbon dioxide and water showed similar abilities to desorb PAHs from the more polar (soft) carbon of the CG samples. The combined SFE and water desorption approaches should improve the understanding of PAH sequestration and release from contaminated soils and sediments and provide the basis for subsequent studies using the same samples to compare PAH release with PAH availability to earthworms.

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Section: Resultssupporting

confidence: 89%

Section: Effect Of Pah and Matrix Organic Composition Onmentioning

confidence: 92%

Comparing PAH Availability from Manufactured Gas Plant Soils and Sediments with Chemical and Biological Tests. 1. PAH Release during Water Desorption and Supercritical Carbon Dioxide Extraction

Hawthorne

Poppendieck

Grabanski

et al. 2002

Environ. Sci. Technol.

120

132

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“…Therefore, the contribution of the slow desorbing fraction in solution to the total fraction of desorbed phenanthrene was assumed to be negligible, or to comprise the 'very slowly' desorbing fraction which, admittedly, could not be adequately assessed during a 21 day desorption kinetic study. Reported rate constants for the fast and slow desorbing fraction of HOCs in natural sorbents are in the range of 10 -5-10 -6 s -1 and 10 -7-10 -10 s -1 , respectively (24,(35)(36)(37). Our results show that the fast rate constants for phenanthrene desorption from soils were on the order of 10 -6-10 -7 s -1 after 30 days of sorption, but decreased by several orders of magnitude to 10 -8-10 -9 s -1 after 270 days (Table 4).…”

Section: Resultsmentioning

confidence: 99%

Mechanistic Characterization of Adsorption and Slow Desorption of Phenanthrene Aged in Soils

Abu

Smith

2006

Environ. Sci. Technol.

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Long-term adsorption of phenanthrene to soils was characterized in a silt-loam (LHS), a sandy soil (SBS), and a podzolized soil (CNS) by use of the Polanyi−Manes model, a Langmuir-type model, and a black carbon−water distribution coefficient (K BC) at a relative aqueous concentration (C e/S w) of 0.002−0.32. Aqueous desorption kinetic tests and temperature-programmed desorption (TPD) were also used to evaluate phenanthrene diffusivities and desorption activation energies. Adsorption contribution in soils was 48−70% after 30 days and 64−95% after 270 days. Significant increases in adsorption capacity with aging suggest that accessibility of phenanthrene to fractions of SBS soil matrix was controlled by sorptive diffusion at narrow meso- and micropore constrictions. Similar trends were not significant for LHS silt-loam or CNS podzol. Analysis of TPD profiles reveal desorption activation energies of 35−53 kJ/mol and diffusivities of 1.6 × 10-7-9.7 × 10-8 cm2/s. TPD tests also indicate that the fraction of phenanthrene mass not diffusing from soils was located within micropores and narrow width mesopores with a corresponding volume of 1.83 × 10-5-6.37 × 10-5 cm3/g. These values were consistent with the modeled adsorption contributions, thus demonstrating the need for such complimentary analytical approach in the risk assessment of organic contaminants.

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“…Based on these physics considerations, a feasible engineering concept for the NCSX has been developed. [23] It provides the space and access provisions to augment the initial configuration with new capabilities, particularly diagnostics [24] and plasma-facing components, as needed in the course of the experimental program.…”

Section: Discussionmentioning

confidence: 99%

Physics Considerations in the Design of NCSX

Monticello

Pavlo

Fu³

et al. 2002

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Compact stellarators have the potential to make steady-state, disruption-free magnetic fusion systems with β ~ 5% and relatively low aspect ratio (R/〈a〉 < 4.5) compared to most drift-optimized stellarators. Magnetic quasi-symmetry can be used to reduce orbit losses. The National Compact Stellarator Experiment (NCSX) is designed to test compact stellarator physics in a high-beta quasi-axisymmetric configuration and to determine the conditions for high-beta disruption-free operation. It is designed around a reference plasma with low ripple, good magnetic surfaces, and stability to the important ideal instabilities at β ~ 4%. The device size, available heating power, and pulse lengths provide access to a high-beta target plasma state. The NCSX has magnetic flexibility to explore a wide range of equilibrium conditions and has operational flexibility to achieve a wide range of beta and collisionality values. The design provides space to accommodate plasma-facing components for divertor operation and ports for an extensive array of diagnostics.

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Diagnostics Plan for the National Compact Stellarator Experiment

Cited by 6 publications

References 1 publication

Comparing PAH Availability from Manufactured Gas Plant Soils and Sediments with Chemical and Biological Tests. 1. PAH Release during Water Desorption and Supercritical Carbon Dioxide Extraction

Comparing PAH Availability from Manufactured Gas Plant Soils and Sediments with Chemical and Biological Tests. 1. PAH Release during Water Desorption and Supercritical Carbon Dioxide Extraction

Mechanistic Characterization of Adsorption and Slow Desorption of Phenanthrene Aged in Soils

Physics Considerations in the Design of NCSX

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