Biosorption of heavy metals by Streptomyces subrutilus (A101) biofilm in a fluidized bed reactor

Tungtakanpoung, Dondej

January 2002

No description available.

628

Desorption

Untersuchung der Mechanismen schwerioneninduzierter Desorption an beschleunigerrelevanten Materialien

Bender, Markus.

Unknown Date

Frankfurt (Main), Universiẗat, Diss., 2008.

Schwerionenbeschleuniger. Desorption.

Reactions of sulphur and acetylene on a palladium (III) surface

Patterson, C. H.

January 1985

No description available.

541

Thermal desorption tests

The kinetics and dynamics of the liquid surface from molecular beam scattering

Olgun, Asim

January 1997

No description available.

541

Inelastic; Desorption

1,2-dihalocarbon adsorption on Cu(111)

Turton, Sarah

January 1997

No description available.

541

Surface science; Desorption

Study of Mechanism in Desorption Electrospray and To Improve the Process of Droplet Electrospray Ionization

Lin, Yu-Xiang

26 June 2006

none

desorption electrospray

droplet electrospray

Ortsaufgelöste MALDI-Massenspektrometrie an biologischen und synthetischen Oberflächen

Bouschen, Werner.

January 2004

Giessen, Universiẗat, Diss., 2004.

Matrix-unterstützte Laser-Desorption

Untersuchungen zum Einbau von Analytionen in MALDI-Matrizes sowie zur Ionisation und Adduktbildung in der MALDI-Massenspektrometrie

Krüger, Ralf.

January 2003

Frankfurt (Main), Universiẗat, Diss., 2003.

Matrix-unterstützte Laser-Desorption

Bioavailability of slower desorbing fractions of sediment-associated permethrin

Rothert, Amanda Kay

01 December 2010

The current study assessed the bioavailability of slower desorbing sediment-associated permethrin by manipulating the desorption properties of two sediments with an absorbent, Amberlite XAD-4. The two sediments differed in OC content and the size of the rapidly desorbing pool and rate constants were smaller in the higher OC sediment. Manipulation decreased desorption rate constants in the treated sediments compared to the untreated sediments. Greater activity of permethrin in the pore water was observed in the lower OC sediment compared to the higher OC sediment, and in the untreated sediment compared to the treated sediment. The higher occurrence of permethrin in the pore water was attributable to the larger pool of rapidly desorbing compound. Based on BAF calculations, bioaccumulation of permethrin by all three species was lower in the higher OC sediment compared to the lower OC sediment, and bioaccumulation was also lower in the treated sediments compared to the untreated sediments for Lumbriculus variegatus and Hexagenia sp., suggesting that bioavailability was reduced for those organisms. Desorption rate constants suggest that a reduction in desorption was the cause. However, bioaccumulation was not reduced for Hyalella azteca whose body residues were not significantly different between the two treatments and so BAF values did not reflect a reduction in bioavailability. The results for H. azteca do not match with typical observations, where bioaccumulation decreases with decreased desorption; suggesting that an important exposure pathway for those organisms was not influenced heavily by the sediment desorption properties. Therefore, the role of ingestion was investigated as a route of uptake. Synthetic digestive fluid extractions increased desorption compared to water; indicating that ingestion increased desorption, and thus bioavailability of sediment-associated permethrin. Estimated pore water and feeding contributions suggested that more than one route of exposure contributed to the uptake of permethrin, and that neither exposure route was responsible for uptake alone. The contribution from feeding was estimated to be greater than the contribution from pore water for WBS sediment for all three species, and for the treated sediments compared to the untreated sediments; indicating that as desorption decreases, the role of ingestion in uptake increases. Therefore, pore water may be more important to the contribution of uptake for faster desorbing compound, and ingestion may be more important to the contribution of uptake for slower desorbing compound.

bioavailability

desorption

pyrethroid

sediment

Desorption Kinetics of Lead from Goethite: Effect of Mixing and Sorption Period

Garman, Stephanie Michelle

10 March 2006

In natural systems, the solution concentration and hence, potential bioavailability of trace metals is primarily controlled by adsorption-desorption reactions at the mineral-water interface. While many studies have been conducted to understand the adsorption of trace metals to soil minerals, less is known about long-term adsorption/desorption processes. In this study, we examined the influence of mixing and sorption period on the desorption of lead from goethite. Lead sorption was rapid and essentially complete in 1 h, with no change in the quantity of lead adsorbed over the 6 month sorption period. Desorption of lead was slower than the adsorption reaction and was best modeled by two first order equations. At all sorption densities, the desorption of lead followed the order Short-term (24 h) > Long-term non-stirred (6 months) > Long-term stirred (6 months). However, statistical analysis indicated that these differences were not statistically significant. Furthermore, the desorption rate coefficients were very similar for all the experiments indicating that there was no significant residence time effect in this study. However, a sample from a previous study that was allowed to age 5 years and then analyzed by the desorption procedure did have statistically significant differences between the long-term (5 years) and the short-term (5 months). These results suggest that longer adsorption periods, perhaps a number of years, may be necessary to determine if residence time effects are an artifact of the experimental conditions or truly the length of the adsorption period. / Master of Science

Miscible Displacement

Desorption

Lead