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A kinetic study of the oligomerization of propene, butene and various hexenes over solid phosphoric acidMcClean, Deaghlan Martin 22 November 2016 (has links)
No description available.
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The Reactions and Emission Spectra of Propylene in Electrodeless DischargeArmstrong, Andrew Thurman 05 1900 (has links)
This thesis describes the reactions and emission spectra of propylene under radio frequency energy radiation.
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Structure/property relationships of commercial propylene/1-pentene random copolymersLutz, Marietjie 03 1900 (has links)
Thesis (PhD (Chemistry and Polymer Science))--University of Stellenbosch, 2006. / Propylene/1-pentene random copolymers are a relatively new family of random copolymers being prepared by Sasol Polymers and reveals high impact strength, good tensile properties, excellent optical properties, good rheological properties and a large pool of processing possibilities. These commercial copolymers are being prepared with stereospecific heterogeneous Ziegler-Natta catalytic systems containing multiple active sites and therefore producing copolymers with a varying degree of stereoregularity. Two different groups of propylene/1-pentene random copolymers were received by Sasol Polymers and investigated in this project.
The first group (Group 1, Polymers A - F) consisted of six totally different batches of commercial propylene/1-pentene copolymers which were produced by different catalyst systems. All had different melt flow indices (MFIs) and different 1-pentene contents and all of the copolymers, except for one, were nucleated. The second group (Group 2, Polymers G - J) were produced by the same catalyst, but with varying donor:catalyst ratios and also differing in their 1-pentene content. Investigation of the Group 1 copolymers was used in order to construct a “molecular toolbox” which was then used to study the Group 2 copolymers.
The original commercial copolymers were all studied by various analytical techniques: high-temperature carbon thirteen nuclear magnetic resonance spectroscopy (13C-NMR), high-temperature gel permeation chromatoghraphy (HT-GPC), crystallization analysis fractionation (CRYSTAF), differential scanning calorimetry (DSC), wide angle X-ray diffraction (WAXD) and positron annihilation lifetime spectroscopy (PALS).
The random copolymers were all fractionated by preparative TREF and the fractions analyzed utilizing the following analytical techniques: 13C-NMR, HT-GPC, CRYSTAF and DSC. The results of these analyses were used to investigate inter alia the distribution of 1-pentene in the copolymers.
In order to investigate the low molecular weight material of the copolymers, which were part of the room temperature fraction during TREF, solvent extractions were carried out using different solvents and different extraction techniques. A complete structural analysis study was carried out on the extracts. The percentages of xylene-solubles were also determined during the quantitative xylene extraction study of the copolymers. Characterization of the xylene non-soluble material was carried out using 13C-NMR, HT-GPC, CRYSTAF, DSC and WAXD in order to compare the properties of the unextracted copolymers with the material after removal of the xylene soluble fraction. Positron annihilation lifetime spectroscopy (PALS) was used as an alternative investigation method for the Group 1 copolymers and their XNS fractions in order to determine what type of information this novel analytical method could generate and how the results compared with those of previous PALS studies on poly-olefins.
A new fractionation technique, preparative solution fractionation (SF), was developed and evaluated. The commercial propylene/1-pentene copolymers were fractionated using this novel technique, the fractions were analyzed by 13C-NMR, HT-GPC, CRYSTAF and DSC and the results were compared with previously existing fractionation methods, namely TREF and CRYSTAF.
A final study was done on the random copolymers by blending one of the commercial Ziegler-Natta catalyzed propylene/1-pentene copolymers with a tailored, low 1-pentene content, metallocene propylene/1-pentene copolymer in different ratios. The blends were analyzed by molecular weight, thermal and crystal phase analysis in order to investigate the effect of the tailored, highly isotactic propylene/1-pentene copolymer on the properties the commercial random copolymers.
Throughout the project the influence of the 1-pentene as well as the donor:catalyst ratio on the copolymers was investigated. This study, in its entirety, therefore allow a better understanding of the effects that the commercial, heterogeneous, transition metal catalysts have on the make up of the copolymers and, by extension, the ultimate properties of the materials.
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Ethylene and propylene copolymers utilizing Fishcer-Tropsch 1-olefinsJoubert, D. J. (Dawid Johannes) 12 1900 (has links)
Thesis (PhD)--Stellenbosch University, 2000. / ENGLISH ABSTRACT: From the Sasol Fischer- Tropsch process, a variety of different a-olefins are produced.
Sasol recently started presenting these a-olefins to polymer producers. To
demonstrate the application possibilities of these a-olefins as comonomers for
ethylene and propylene polymerization, it was necessary to first synthesize catalysts
having a combination of high activity and good comonomer incorporation, and in the
case of propylene copolymers, also sufficient stereospecificities.
Different methods to produce catalysts conforming to these requirements were
investigated and it was found that catalysts produced from a MgCb-support activated
by a combination of chemical and mechanical means produced suitable catalysts. The
amount of alcohol used during the support activation step and the time allowed for
alkylation of the active centers were important. No clear correlation between total
titanium content and activity was observed. The degree to which active sites are
protected was evaluated from the amount of comonomer present in the final copolymer
based on the amount added to the reaction. Cyclopentadiene was used to selectively
deactivate the unprotected active sites to determine the ratio between protected and
"open" active sites. High activity catalysts are not suitable for gas-phase
copolymerization and were consequently "diluted" by dispersion in a pre-formed
polymer powder and by prepolymerization. Catalyst activity based on titanium
content was substantially decreased, but comonomer incorporation was not.
Catalysts for producing crystalline polypropylene require the presence of both an
internal and external electron donor. It was shown that isotacticity increased linearly
with an increase in external modifier at the expense of catalyst activity and that a
double treatment of the support or catalyst before the final TiCl4 fixation was more
effective at increasing stereospecificity. The less stereospecific sites are more capable of accepting bulky comonomers in the coordination complex and thus by decreasing
the amount of less-stereospecific active sites, the overall capability of the catalyst to
incorporate comonomer was decreased.
Comonomer sequence distributions and average lamellar thicknesses of different
ethylene / a-olefin copolymers were calculated from CH2 dyad concentrations
determined by I3C NMR spectroscopy. Ethylene sequences in the I-butene
containing copolymers are generally longer than those where a higher a-olefin was
used as comonomer which indicates that a more random comonomer distribution is
obtained when the higher u-olefins are used. It was shown that an inverse
relationship exists between branch size and density. For density, no effect resulting
from the comonomer type was observed. This same inverse relationship was also
observed for tensile strength. Modulus, hardness and impact strength, on the other
hand, did show an effect resulting from the comonomer type. Modulus and hardness
were not depressed as much and impact strength improved more than what was
expected from calculations based on branch size. Homogeneous copolymers have
broad melting peaks. It was shown that at sufficiently high comonomer content, peak
broadening occurs when the higher cc-olefins are used as comonomer, which also
indicates that more random comonomer distributions are obtained with the higher aolefins.
From the chain propagation probabilities calculated it was observed that two
types of active sites are present. Those responsible for producing mainly
polyethylene have an alternating character while the sites capable of incorporating
comonomer have a blocky character.
It was expected that the additional introduction of a third a-olefin during ethylene / 1-
pentene copolymerization will produce a terpolymer with density and related
properties similar to the mathematical average between those of the relevant
copolymers. This was only observed for the terpolymers containing l-heptene, 1-
octene and l-nonene. The I-butene containing terpolymers have densities well below
the expected values while the I-hexene containing terpolymers have values very
similar to that of the ethylene / l-hexene copolymer densities, but still below the
expected values. Properties related to density, such as tensile strength and modulus,
follow this same trend. It is believed that the presence of l-pentene breaks up the tendency of the lower c-olefins to cluster which results in improved randomness.
Compared to the copolymers, I-butene and l-hexene containing terpolymers seem to
reach the impact strength maximum at a lower total comonomer content than that of
the I-pentene copolymers which also indicates an enhanced effect from the combined
use of I-pentene with these o-olefins. No substantial difference between impact
strengths of co- and terpolymers prepared with higher a-olefins was observed.
In general, the melting temperatures of the terpolymers are slightly lower and spread
over a wider temperature range than those of the copolymers which can be realized if
the comonomer units are less clustered and thus more randomly distributed. Decrease
in melting temperature was, however, not as much as for the metallocene catalyzed
terpolymers.
From sequence length calculations from l3C NMR spectroscopy it was found that the
crystallizable ethylene sequences of l-butene containing terpolymers were shorter
than those of the corresponding copolymers, which confirms the notion that the
introduction of a third comonomer resulted in an increase in randomness.
Crystallizable sequence lengths became gradually shorter when higher cc-olefins were
used in co- and terpolymers and those of the terpolymers are generally shorter.
From the different types of active centers present on a Ziegler-Natta catalyst, it was
reasoned that three main types of polymer chains can be present in the terpolymers:
(a) ethylene homopolymer, (b) ethylene / lower a-olefin copolymer and (c) ethylene /
lower a-olefin / higher a-olefin terpolymer. The ratio between these components in
the final terpolymer depends primarily on the size of the higher a-olefin. The larger
the third a-olefin becomes, the more active sites will reject it, resulting in a higher
amount of ethylene / lower a-olefin copolymer. It was thus suggested that the large
decrease in density and the associated change in related properties observed for
ethylene / l-pentene / l-butene terpolymers can be related to the combined result of
improved random comonomer incorporation together with the decrease in the amount
of ethylene homopolymer. The possibilities of using the higher a-olefins having uneven carbon numbers were
investigated in random propylene copolymers. Similar to that observed for the
ethylene copolymers, less of the higher a-olefins was necessary to achieve a certain
level of crystallinity. A good agreement was observed between tensile properties and
comonomer type and content and the size of the branch and the resulting defect it
causes in the crystal structure is the primary factor affecting tensile strength. For
impact strength a close correlation between the size of the comonomer side chain and
comonomer content was observed. It was shown that the effect of the heptyl branch
derived from a l-nonene unit was 2.3 times that of the propyl group derived from the
I-pentene unit.
Properties of block copolymers can not be related directly to l-pentene content as is
the case with random copolymers, mainly due to the heterogeneity of the block
copolymers. The activating effect of hydrogen on catalyst activity was observed. It
was also observed that the amount of l-pentene incorporated in the copolymer as well
as the copolymer yield were higher in the presence of hydrogen than when the
reaction was carried out in the absence of hydrogen.
By using DSC it was possible to identify different crystalline phases in the propylene
/ I-pentene block copolymers due to the differences in their crystallization kinetics. A
connection between the low-temperature peak and impact strength was observed. It
was found that the presence of the low-temperature peak resulting from thin lamellae
formed by chain containing many defects was undesirable when high impact strength
is required. It was not possible to quantify the extent to which the intensity of this
peak affected mechanical properties of the block copolymers. However, from
sequence length calculations it was found that the ratio between the propylene and 1-
pentene sequence lengths could be related quantitatively to impact strength, modulus,
hardness and tensile strength of the polymers investigated. / AFRIKAANSE OPSOMMING: 'n Verskeidenheid van verskillende «-olefiene word in die Sasol Fischer- Tropsch
proses vervaardig. Sasol het onlangs begin om hierdie a-olefiene aan
polimeervervaardigers te bied. Om die toepassingsmoontlikhede van hierdie aolefiene
as komonomere vir etileen en propileen polimerisasie te demonstreer was dit
nodig om eerstens 'n katalis met 'n kombinasie van hoë aktiwiteit en goeie
komonomeer invoeging te sintetiseer. In die geval van propileen word voldoende
stereospesifisiteit ook vereis.
Verskillende metodes om kataliste wat aan hierdie vereistes voldoen te vervaardig is
ondersoek. Daar is gevind dat kataliste waarvan die MgCb basis deur 'n kombinasie
van chemiese- en meganiese metodes geaktiveer is, die vereiste eienskappe besit. Die
hoeveelheid alkohol gebruik tydens die basis aktivering stap en die tyd toegelaat vir
die alkilering van die aktiewe spesies was belangrik. Geen duidelike verband tussen
totale titaan inhoud en aktiwiteit is waargeneem nie. Die mate waartoe aktiewe
spesies beskerm is, is bepaal vanaf die hoeveelheid komonomeer teenwoordig in die
finale kopolimeer in verhouding met die hoeveelheid bygevoeg tydens die reaksie.
Siklopentadieen is gebruik om onbeskermde aktiewe spesies selektief te deaktiveer
om die verhouding tussen beskermde en oop aktiewe spesies te bepaal. Hoëaktiwiteit
kataliste is nie geskik vir gasfase kopolimerisasie nie en is gevolglik verdun
deur dit te versprei in 'n voorafgevormde polimeer poeier en deur prepolimerisasie.
Katalis aktiwiteit gebaseer op titaan inhoud was aansienlik laer maar komonomeer
invoeging was nie merkbaar beinvloed nie.
Kataliste VIr die vervaardiging van kristallyne polipropileen vereis die
teenwoordigheid van beide interne- en eksterne elektron donors. Daar is gewys dat
isotaktisiteit liniêr verhoog met 'n toename in eksterne modifiseerder ten koste van katalis aktiwiteit en dat 'n dubbele behandeling van die basis of katalis, voor die finale
titaan fiksering, meer effektief was om stereospesifisiteit te verhoog. Die spesies met
laer stereospesifisiteit is meer bevoeg om bonkige komonomere in die koërdinasie
kompleks toe te laat en deur dus die konsentrasie van hierdie spesies te verlaag is die
bevoegdheid van die katalis om bonkige komonomeer te inkorporeer, verlaag.
Komonomeer reeksverspreiding en gemiddelde lamellêre dikte van verskillende
etileen / o-olefien kopolimere is bereken vanaf CH2 diad konsentrasie bepaal deur
KMR spektroskopie. Etileen reekse in die kopolimere wat l-buteen bevat is oor die
algemeen langer as dié waarin 'n hoër a-olefien as komonomeer gebruik was, wat
aandui dat 'n meer egalige komonomeer verspreiding verkry word as hoër «-olefiene
gebruik word. Daar is getoon dat 'n inverse verhouding tussen die grootte van die
vertakking en digtheid bestaan. Geen effek komende van die komonomeer tipe kon
waargeneem word nie. Hierdie soortgelyke inverse verhouding was ook waargeneem
vir treksterkte. Modulus, hardheid en impaksterkte aan die ander kant, hét 'n effek
komende van die komonomeer tipe getoon. Modulus en hardheid was nie soveel
verlaag, en impak sterkte soveel verhoog as wat verwag is vanaf berekeninge
gebaseer op vertakking grootte nie. Homogene kopolimere toon breë smeltpieke.
Daar is gewys dat by voldoende komonomeer inhoud 'n verbreding van die pieke
voorgekom het wanneer hoër a-olefiene as komonomere gebruik is, wat ook aandui
dat 'n meer egalige komonomeer verspreiding met hierdie c-olefiene verkry kan
word. Vanaf berekening van die ketting voortplantingsmoontlikhede is waargeneem
dat twee tipes aktiewe spesies teenwoordig is. Die verantwoordelik vir die vorming
van polietileen het 'n alternerende karakter terwyl die sentra wat komonomeer kan
inkorporeer 'n blokagtige karakter het.
Daar is verwag dat die addisionele byvoeging van 'n derde o.-olefien tydens etileen /
I-penteen kopolimerisasie, 'n terpolimeer met digtheid en verwante eienskappe
soortgelyk aan die wiskundige gemiddelde tussen dié van die relevante kopolimere tot
gevolg sal hê. Dit was egter slegs waargeneem vir terpolimere wat I-hepteen 1-
okteen en l-noneen bevat. Die I-buteen bevattende terpolimere het digthede ver
onder die verwagte waardes terwyl die I-hekseen bevattende terpolimere waardes
soortgelyk aan die etileen / l-hekseen kopolimeer digthede het' wat steeds onder die verwagte waardes is. Eienskappe verwant aan digtheid, soos treksterkte en modulus,
volg dieselfde neiging. Dit word geglo dat die teenwoordigheid van l-penteen die
neiging van die laer a-olefiene om saam te bondelopbreek wat 'n verbeterde
egaligheid in komonomeerverspreiding tot gevolg het. Vergeleke by die kopolimere
blyk dit dat die terpolimere wat l-buteen en I-hekseen bevat, die impaksterkte
maksimum by 'n laer totale komonomer inhoud bereik as dié van die 1-penteen
polimere. Dit dui ook op 'n verbeterde effek as gevolg van die gekombineerde
gebruik van l-penteen met ander a-olefiene. Geen duidelike verskil tussen die
impaksterktes van ko- en terpolimere, wat met die hoër a-olefiene berei was, is
waargeneem me.
In die algemeen is die smeltingstemperature van die terpolimere effens laer, en
versprei oor 'n wyer temperatuurgebied as dié van die kopolimere wat verklaar kan
word as komonomere minder saamgebondel is en dus meer homogeen versprei is.
Die afname in smelt temperatuur was egter nie soveel as dié van die metalloseengekataliseerde
terpolimere nie.
Vanaf reekslengte berekeninge met behulp van KMR spektroskopie is daar gevind dat
die kristalliseerbare etileen reekse van die l-buteen bevattende terpolimere korter was
as dié van die ooreenkomstige kopolimere, wat die gevoel dat die byvoeging van 'n
derde komonomeer 'n verbeterde komonomeerverspreiding tot gevolg het, bevestig.
Vanaf die verskillende aktiewe spesies teenwoordig in 'n Ziegler-Natta katalis is daar
geredeneer dat drie hooftipes polimeerkettings in die terpolimere teenwoordig kan
wees: (a) etileen hompolimeer, (b) etileen / laer a-olefien kopolimeer en (c) etileen /
laer a-olefien / hoër a-olefien terpolimeer. Die verhouding tussen hierdie
komponente in die finale terpolimeer hang primêr van die grootte van die hoër aolefien
af. Hoe groter die derde a-olefien is, deur hoe meer van die aktiewe spesies
sal dit verwerp word wat 'n groter hoeveelheid etileen / laer a-olefien kopolimeer tot
gevolg sal hê. Daar word dus voorgestel dat die groot afname in digtheid en die
geassosieerde veranderings in die toepaslike eiensappe waargeneem vir etileen / 1-
penteen / I-buteen terpolimeere, herlei kan word na die gekombineerde effek van verbeterde komonomeerverspreiding tesame met die afname lil die hoeveelheid
etileen homopolimeer.
Die moontlikheid om hoër cc-olefiene met onewe koolstofgetalle te gebruik in
homogene propileen kopolimere is ondersoek. Soortgelyk aan dit wat waargeneem is
vir die etileen kopolimere, was minder van die hoër cc-olefiene nodig om 'n spesifieke
vlak van kristalliniteit te bereik. 'n Goeie ooreenkoms tussen trek-eienskappe en .
komonomeer tipe- en inhoud is waargeneem en die grootte van die vertakking en die
gevolglike defek wat dit veroorsaak in die kristal struktuur is die primêre faktor wat
treksterkte beinvloed. Vir impaksterkte is 'n noue verband tusssen die grootte van die
vertakking en komonomeer inhoud waargeneem. Daar is aangetoon dat die effek van
die heptiel vertakking vanf die l-noneen eenheid 2.3 keer dié van die propiel groep
van die l-penteen eenheid is.
Eienskappe van blok kopolimere kan nie direk na l-penteen inhoud herlei word soos
die geval met die homogene kopolimere was nie, hoofsaaklik as gevolg van die
heterogeniteit van die blok kopolimere. Die aktiverende effek van waterstof op katalis
aktiwiteit is waargeneem. Daar is ook gesien dat die hoeveelheid l-penteen
geïnkorporeer in die kopolimeer, sowel as die kopolimeer opbrengs, hoër was in die
teenwoordigheid van waterstof as wanneer die reaksie sonder waterstof uitgevoer is.
Deur DSC te gebruik was dit moontlik om verskillende kristallyne fases in die
propileen / l-penteen blok kopolimere vanaf die verskille in hulle krisallisasie
kinetika, te identifiseer. 'n Verbintenis tussen die lae-temperatuur piek en
impaksterkte is waargeneem. Daar is gevind dat die teenwoordigheid van die laetemperatuur
piek, komende van die dun lamellas gevorm, deur kettings wat baie
defekte bevat, ongewens is wanneer hoë impaksterkte vereis word. Dit was nie
moontlik om die bereik waartoe die intensiteit van hierdie piek die meganiese
eienskappe van die blok kopolimere affekteer, te kwantifiseer nie. Vanaf reekslengte
bepalings is daar gevind dat die verhouding tussen die propileen en I-penteen
reekslengtes kwantitiatief herlei kan word na impaksterkte, modulus, hardheid en
treksterkte van die ondersoekte polimere.
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Adamantane copolymersCoetzee, Liezel 12 1900 (has links)
Thesis (PhD)--Stellenbosch University, 2001. / ENGLISH ABSTRACT: This study concerns the incorporation of adamantane containing monomers
3-(1-adamantyl)-1-propene and 1-(1-adamantyl)-4-vinylbenzene into ethene,
propene and higher a-olefins using different catalytic systems. The effect of the
incorporation of the adamantane monomer on the physical and thermal
properties of the polymers was investigated. A thorough study on the
background of adamantane in general, as well as polymerization reactions
involving the above-mentioned monomers and a-olefins was done.
3-(1-Adamantyl)-1-propene as well as 1,.(1-adamantyl)-4-vinylbenzene was
sucessfully synthesized. The homo polymers of each monomer were made. The
above-mentioned monomers were also polymerized:
• . 3-( 1-adamantyl)-1-propene with ethene, propene and higher a-olefins,
• 1-(1-adamantyl)-4-vinylbenzene with ethene and styrene.
The copolymers of 3-(1-adamantyl)-propene as well as 1-(1-adamantyl)-
4-vinylbenzene were characterized as far as possible to show the influence
of the incorporation of the adamantane group on the physical and chemical
properties of the polymers. A series of 3-phenyl-1-propene copolymers with
higher a-olefins were synthesized to compare the influence of the phenyl
group to the adamantyl group on the relevant properties of the polymers. / AFRIKAANSE OPSOMMING: Hierdie studie behels die inkorporasie van adamantaan-bevattende monomere,
3-( 1-adamantiel)-1-propeen en 1-(1-adamantiel)-4-vinielbenseen in eteen,
propeen en hoër a-olefiene met behulp van verskillende katalitiese sisteme. Die
effek wat die inkorporasie van die adamantaan monomeer op die fisiese en
chemiese eienskappe van die polimere het, is ondersoek. 'n Deeglike studie van
die agtergrond van adamantaan in die geheel, sowel as die polimerisasie
reaksies van die bogenoemde monomere met a-olefiene, is gedoen.
3-( 1-Adamantiel)-1-propeen sowel as 1-(1-adamantiel)-4-vinielbenseen is
suksesvol berei. Die homopolimere van bogenoemde monomere is
gesintetiseer. Bogenoemde monomere is gepolimeriseer:
• 3-(1-adamantiel)-1-propeen met eteen, propeen en hoër a-olefiene,
• 1-(1-adamantiel)-4-vinielbenseen met eteen en stireen.
Die kopolimere van 3-(1-adamantiel)-1-propeen en 1-(1-adamantiel)-
4-vinielbenseen is sover moontlik gekarakteriseer om die invloed van die
adamantaan groep op die fisiese en chemiese eienskappe van die polimeer
te toon. 'n Reeks kopolimere van 3-(1-feniel)-1-propeen met hoër a-olefiene
is gesintetiseer om die verwantskap tussen die invloed van die fenielgroep
en die adamantielgroep op die relevante eienskappe van die polimere te
toon.
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A MATRIX ISOLATION SPECTROSCOPIC INVESTIGATION INTO THE REACTION PRODUCTS OF VANADIUM METAL ATOMS WITH PROPENEWalker, Stephen 17 August 2009 (has links)
The products of vanadium metal atom reactions with propene and some propene isotopomers (propene-d6 and propene-3,3,3-d3) are investigated using FT-IR matrix isolation. The major product from the condensation of V atoms with propene at elevated mole ratios is found to be propane (C3H8), the production of which is seen to increase as concentration of propene increases. Additionally a matrix isolated product formed after metal atom insertion into the C-H bond of propene at low propene mole ratios is isolated and identified.
The location of the insertion site is identified as one of the methyl hydrogen carbon bonds. The structure of the product is identified as an allyl vanadium hydride complex, through a FT-IR matrix isolation study of propene isotopomers. It is also shown that this primary product acts as an intermediate in the formation of propane. A full mechanism for the proposed formation of propane from sacrificial hydrogenation is proposed and compared with the reported mechanism for the similar reaction involving ethene. The mechanistic identification of the hydrogenation of propene is shown as a generalization of the previous reaction involving ethene.
Photochemistry of reactants and intermediates trapped in the matrix are investigated. Irradiation of matrices with several different UV-visible wavelength ranges indicate that no further chemistry occurs after formation of the matrix and further irradiation has no effect on intermediates or reactants. Additionally the reactivity of water with vanadium and propene under low propene concentration conditions is also studied. Results from this study show that under all conditions studied no incorporation of water into the propene molecule is found. / Thesis (Master, Chemistry) -- Queen's University, 2009-08-10 11:15:55.312
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Selective oxidation of propylene to acrolein over vanadium and niobium doped bismuth molybdatesLi, Xin. January 2009 (has links)
Thesis (M.Ch.E.)--University of Delaware, 2008. / Principal faculty advisors: Mark A. Barteau and Douglas J. Buttrey, Dept. of Chemical Engineering. Includes bibliographical references.
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Catalytic oxidation of ethylene and propylene in a solid electrolyte cellStoukides, Michael January 1982 (has links)
Thesis (Ph.D.)--Massachusetts Institute of Technology, Dept. of Chemical Engineering, 1982. / MICROFICHE COPY AVAILABLE IN ARCHIVES AND SCIENCE / Includes bibliographical references. / by Michael Stoukides. / Ph.D.
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The partial oxidation of propene to acrolein over single-crystal Cu₂OSchulz, Kirk H. 26 February 2007 (has links)
The partial oxidation of propene (CH₂=CHCH3) to acrolein (CH₂=CHCHO) has been studied over Cu₂0(100) and (111) single crystal surfaces. Propene adsorption under ultrahigh vacuum conditions yields no significant oxidation products, but the propene desorption temperatures are sensitive to the structural differences in the surfaces.
Propene adsorption at atmospheric pressure followed by thermal desorption in ultrahigh vacuum demonstrates that propene may be activated at higher pressures. Over the nonpolar Cu₂0(111) surface, lattice oxygen insertion occurs at 300 K and 1 atm. with the formation of the σ-bonded allyl intermediate. Once formed, this specie is stable in ultrahigh vacuum and produces acrolein during TDS via a reaction-limited process. A comparison of these data with studies of allyl alcohol decomposition over Cu₂O surfaces indicate that the σ-bonded intermediate is surface allyloxy (CH₂=CH-CH₂0-) which dehydrogenates to acrolein via hydride elimination on the carbon α to the oxygen. Thus, oxygen insertion precedes the final hydrogen abstraction in the partial oxidation pathway. Propene is also observed during allyl alcohol decomposition indicating that the transformation of the π-allyl to the σ-allyl (allyloxy) during propene oxidation is reversible.
The structure sensitivity of the propene oxidation reaction is demonstrated by the lack of acrolein production from the Cu-terminated, Cu₂0(100) surface following 1 atm. propene exposures. The origin of the structure sensitivity is related to the absence of coordinately-unsaturated lattice oxygen anions on the (100) surface. / Ph. D.
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Heterogen katalysierte Gasphasen-Epoxidation von Propen an FeOx/SiO2-KatalysatorenDuma, Viorel 14 August 2001 (has links) (PDF)
Im Rahmen der vorliegenden Arbeit wurde eine neuartige Methode und die entsprechenden Katalysatoren für die heterogen katalysierte Gasphasen-Epoxidation von Propen entwickelt und optimiert. Das Propen wurde an FeOx/SiO2-Katalysatoren mit N2O als Oxidationsmittel epoxidiert. Die Katalysatoren wurden mittels XRD, TEM, XPS, Physi- und Chemisorption, TPR/TPO, TPD und IR untersucht und charakterisiert. Der Einfluß der Reaktionsbedingungen auf die Oxidationsergebnisse wurde bestimmt und Untersuchungen zum Reaktionsablauf durchgeführt. Es wurden Selektivitäten zu Propenoxid von 40-70%, bei Propenumsätzen von 3-12%, erreicht. Die maximalen erzielten PO-Ausbeuten betrugen über 5%, und sind damit den berichteten Ergebnisse aus der Literatur überlegen.
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