E. E. Hennecke scite author profile

E. E. Hennecke

3Publications

36Citation Statements Received

5Citation Statements Given

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Affiliations

Missouri University of Science and Technology

Publications

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Polymerization of para‐xylylene derivatives (parylene polymerization). I. Deposition kinetics for parylene N and parylene C

Kramer

Sharma

Hennecke

et al. 1984

J. Polym. Sci. Polym. Chem. Ed.

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Kinetic aspects of parylene N [unsubstituted poly(para‐xylylene)] and Parylene C [monochlorosubstituted poly(para‐xylylene)] were studied. The conversion of starting material (dimer of either p‐xylylene or chloro‐para‐xylylene) to polymer is quantitative (ca. 100%). Consequently, the total polymer formed in a closed system is directly proportional to the amount of dimer charged. However, the percentage of the total amount of polymer formed which deposits on substrate surfaces, placed in the deposition chamber, as well as the polymer film growth rate are dependent on operational factors such as the temperature of the substrate, sublimation of dimer temperature, flow pattern of the reactive species, etc. Parylene C, being a heavier and more polar molecule, has the tendency to deposit easily in the deposition chamber compared to the deposition of Parylene N. Parylene C also has a higher ceiling temperature for deposition than Parylene N. This situation has been investigated from the viewpoint of excess thermal energy which hinders polymer formation (deposition) due to the exceedingly high entropy change necessary for polymer deposition to occur. The addition of a cool (i.e., room temperature) inert gas was shown to increase the deposition of Parylene N on substrate surfaces placed in the deposition chamber. The deposition increase and acceleration of deposition (film growth) rate were found to be related to the size and molecular weight of the inert gas pressure maintained in the system. The accelerating effect is explained by the increase in third‐body collisions to dissipate the excess thermal energy of the reactive species.

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The effect of plasma-deposited polymers on the nucleate boiling behavior of copper heat transfer surfaces

Hinrichs

Hennecke

Yasuda

1981

International Journal of Heat and Mass Transfer

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Preparation and characterization of composite hollow fiber reverse osmosis membranes by plasma polymerization. 1. Design of plasma reactor and operational parameters

Heffernan¹,

Yanagihara²,

Matsuzawa³

et al. 1984

Ind. Eng. Chem. Prod. Res. Dev.

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Ind. Eng. Chem. Prod. Res. Dev. 1984, 23, 153-162 153 (Y = probability of chain propagation density) of species i Registry No. Carbon monoxide, 630-08-0; ruthenium, 1440-18-8. Literature Cited Batchelder. R. F.; Pennllne, H. W.; Schehl, R. R. Technlcal Publication DOE/ PETC/lR-83/6, US.Composite hollow fiber reverse osmosis membranes were prepared by depositing a thin layer (10-50 nm) of plasma polymers on hollow fibers wlth porous walls (made of polysulfone). The coating was canied out in a semicontinuous manner with six strands of substrate fibers. Operational parameters which influence reverse osmosis characteristics of composRe membranes were investigated.

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E. E. Hennecke

Polymerization of para‐xylylene derivatives (parylene polymerization). I. Deposition kinetics for parylene N and parylene C

The effect of plasma-deposited polymers on the nucleate boiling behavior of copper heat transfer surfaces

Preparation and characterization of composite hollow fiber reverse osmosis membranes by plasma polymerization. 1. Design of plasma reactor and operational parameters

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