Catalyst conductivity

Perform a single-gauge pressure survey around the feed nozzles. Calculate the hydrogen content of the spent catalyst. Conduct a... 

A two stage CSTR with slurried catalyst conducts a reaction with rate equation... 

This monograph describes research on bimetallic catalysts conducted at the Exxon Research and Engineering laboratories since the early 1960s. Much of the monograph is concerned with research directed toward the validation and elucidation of the bimetallic cluster concept. Some discussion is devoted also to the technological aspects of these systems, with emphasis on their application for the catalytic reforming of petroleum fractions. 

This monograph is an account of research on bimetallic catalysts conducted in the laboratories of the Exxon Research and Engineering Company from the early 1960s to the present. The research began in the old Process Research Division of the company. Subsequently, it was transferred to the Central Basic Research Laboratories, the forerunner of the Corporate Research Laboratories organized in 1968. Most of the research discussed here was conducted in the Corporate Research Laboratories. 

An important feature of both manganese oxides and the Mo-V oxide is that they are redox active. Therefore, applications as catalysts, conductive materials, and electrode materials have been investigated. For example, both the manganese oxides and the Mo-V oxide have excellent catalytic activity for selective oxidation of organic molecules. However, catalytic activity characteristic of ordered porosity has not yet been reported, because pores are so small that only very small organic molecules can enter the pores. 

Wall thickness 1.7 nm Catalyst, conductive material Pore Nanowires (TEM) [69]... 

Ammonia Dibutyltin maleate Dibutyltin oxide Fluorosulfonic acid Phosphine Sodium ethylate Sodium hydride Tetrabutyl titanate Tetraisopropyl titanate p-Toluene sulfonic acid Zirconium butoxide catalyst, condensation reactions Dibutyltin diacetate Piperidine catalyst, conductive polymers Iron (III) toluenesulfonate catalyst, conversion of acetylene to acetaldehyde Mercury sulfate (ic) catalyst, copolymerization Di butyl ether catalyst, cracking Zeolite synthetic... 

When the reactant is a low-solubility gas it is advantageous to minimize mass-transport effects by employing a porous-gas electrode. The electrode is manufactured by compressing catalyst, conducting powder (e.g. graphite) and perhaps a... 

---