Walter E. Foster scite author profile

removed by filtration, washed with ether, and air-dried. The dry solid melted at 170-172' and weighed 0.75 gram (71%). Evaporation of the solvent on the steam bath gave an additional 50 to 100 milligrams of yellow solid (m.p. 165-168').The crude product waa recrystallized from 96y0 ethanol and melted a t 171.0-172.0°.Anal. Calcd. for C1aHlaNO,: 63.15% C, 5.30% H. Found:Acid hydrolysis of ethyl 9-benzoxazolylpyruvate methylation product. A mixture of 1 gram of the methylation product described in the preceding section and 25 ml. of 20% hydrochloric acid was heated under reflux for 6 hr. The colorless acidic solution was chilled in an ice bath and neutralized with eodium bicarbonate. A white precipitate formed which darkened rapidly on standing in contact with the aqueous solution. The precipitate, when dried, weighed 0.8 g. The crude material was crystallized from a benzene-petroleum ether mixture and sublimed in Vacuo (at 1 mm. of mercury and 75-85'). The colorless, crystalline product melted a t 63.25% C, 5.467'0 H. 93-95'. The hydrolysis product was proved to be o-methylaminophenol by comparison of melting points and mixture melting points with an authentic sample.27 the authors are grateful for helpful discussions. BETHLEHEM, PA. (27) The melting points were determined simultaneously in the same apparatus, since there is considerable disagreement in the literature regarding the correct melting point of o-methylaminophenol, [CONTRIBUTION FROM THEl RESEARCH AND DEVELOPMENT LABORATORIES O F THE ETHYL CORPOR.4TIOS ]Magnesium hydride was found to add to ethylene, 1-octene, and isobutylene to form the magnesium-carbon bond in low yields. The extent of the reaction appears to be dependent upon the surface or form of the hydride and is limited by the occurrence of side and consecutive reactions, such as solvent cleavage, carbonization, and chain growth. Evidence was obtained for catalysis of the hydride-alkylation reaction by organometallics, such as alkylaluminum and alkylboron compounds. Relevant to the chain growth reaction, it was found that a mixture of magnesium hydride and triethylboron in diethyl ether catalyzed the low-pressure polymerization of ethylene at room temperature to form solid polyethylene.Diethylmagnesium was found to be considerably more reactive than magnesium hydride toward olefins. With ethylene in diethyl ether, 25-35% conversion of diethylmagnesium to n-butylmagnesium compounds was obtained. In hydrocarbon solvents, complete consumption of the diethylmagnesium occurred, with the formation of hydrocarbons containing ten or more carbon atoms per molecule.

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Predicting the Outcome of Endometrial Hyperplasia by Quantitative Analysis of Nuclear Features Using a Linear Discriminant Function

Colgan

Norris

Foster

et al. 1983

International Journal of Gynecological Pathology

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Catalytic Graphite Inclusion Compounds. II. Potassium Graphite as an Alkylation Catalyst

Podall¹,

Foster²

1958

J. Org. Chem.

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Walter E. Foster

Catalytic Graphite Inclusion Compounds. I. Potassium Graphite as a Polymerization Catalyst

The Preparation and Stabilization of Acetylenic Boranes^1a

Reactions of Magnesium Hydride and Diethylmagnesium with Olefins¹

Predicting the Outcome of Endometrial Hyperplasia by Quantitative Analysis of Nuclear Features Using a Linear Discriminant Function

Catalytic Graphite Inclusion Compounds. II. Potassium Graphite as an Alkylation Catalyst

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Walter E. Foster

Catalytic Graphite Inclusion Compounds. I. Potassium Graphite as a Polymerization Catalyst

The Preparation and Stabilization of Acetylenic Boranes1a

Reactions of Magnesium Hydride and Diethylmagnesium with Olefins1

Predicting the Outcome of Endometrial Hyperplasia by Quantitative Analysis of Nuclear Features Using a Linear Discriminant Function

Catalytic Graphite Inclusion Compounds. II. Potassium Graphite as an Alkylation Catalyst

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Product

Resources

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The Preparation and Stabilization of Acetylenic Boranes^1a

Reactions of Magnesium Hydride and Diethylmagnesium with Olefins¹