Catalytic and Thermal Cracking of Pure Hydrocarbons: Mechanisms of Reaction

Abstract: T h e primary cracking of pure hydrocarbons both with and without catalysts has been studied in terms of the distribution by carbon number of the cracked fragments to allow arriving a t a mechanism of molecular disintegration. The secondary reactions of the cracked fragments have been followed by analyses of the product fractions to allow a further definition of the nature of the cracking system. On the basis of this work, cracking systems are assigned to two fundamental classes; each class is described by a s… Show more

“…5.8 % for butane. Such behaviour has been well known for over 60 years [14][15][16] as is the formation of higher molecular weight by-products leading to catalyst coking. Indeed with propyne feed there is a 78 % loss in catalytic activity in 15 min on stream ( Table 1).…”

Transhydrogenation of propyne with butane over a vanadia/θ-alumina catalyst

“…5.8 % for butane. Such behaviour has been well known for over 60 years [14][15][16] as is the formation of higher molecular weight by-products leading to catalyst coking. Indeed with propyne feed there is a 78 % loss in catalytic activity in 15 min on stream ( Table 1).…”

Transhydrogenation of propyne with butane over a vanadia/θ-alumina catalyst

“…472,476 Consequently, the acid sites on (nonshape selective) amorphous aluminosilicates do not release alkenes until they are hexane isomers or smaller. 538,539 Once long alkanes have been cracked that far, the resulting fragments have a high enough free energy of adsorption to be replaced by the longer, unprocessed alkanes and alkenes in the feed. 538,539 Figure 65 shows a representative product slate for the nonshape selective catalytic cracking of n-C 16 .…”

“…538,539 Once long alkanes have been cracked that far, the resulting fragments have a high enough free energy of adsorption to be replaced by the longer, unprocessed alkanes and alkenes in the feed. 538,539 Figure 65 shows a representative product slate for the nonshape selective catalytic cracking of n-C 16 . 539 It only has a single maximum.…”

“…538,539 Figure 65 shows a representative product slate for the nonshape selective catalytic cracking of n-C 16 . 539 It only has a single maximum. In marked contrast to this type of a product distribution with only a single maximum, 538 the catalytic cracking of long n-alkanes on ERI-type zeolites shows two (see Figure 66) or even four maxima (see Figure 67).…”

Molecular Simulations of Zeolites: Adsorption, Diffusion, and Shape Selectivity

“…Primarily, there are two main types of mechanisms that govern acid catalyzed cracking of hydrocarbons [71,72]. They are namely bimolecular (classical) cracking which involves hydride transfer reactions [73] and monomolecular cracking which occur by formation of carbonium ions [74]. The monomolecular (non-classical) cracking proposed by Haag and Dessau [74] extensively occurs in medium pore shape selective zeolites (ZSM-5) [75][76][77] since bimolecular reaction intermediates cannot be formed in the narrow pores.…”

Novel Fast Pyrolysis/Catalytic Technology for the Production of Stable Upgraded Liquids