1 |
Gallosilicate zeolitesLiu, X. January 1986 (has links)
No description available.
|
2 |
Hydrothermal Synthesis Process for the Production of Silicalite-1 Crystal Aggregate Packing ParticlesCarleen, Bradford J 26 January 2010 (has links)
Methyl Tertiary-Butyl Ether (MTBE) contamination of groundwater and surface waters has become a relevant environmental and public safety concern in recent years. This anthropogenic compound is now persistent at low concentrations in several valuable ground and surface water locations within the United States due largely to the widespread production of MTBE for use as a fuel oxygenate in conjunction with negligent underground storage practices during the 1980's and 1990's. Though there are several treatment strategies for the remediation of MTBE spill sites, the most efficient strategy may be adsorption of MTBE by a packed column of silicalite-1 adsorbent. Effective adaption of this technology requires cheap production of silicalite-1 sorbent packing particles on the order of 3 millimeters diameter. This work entails the development of a new synthesis process which results in sufficient in-situ crystallization of silicalite-1 aggregates within a 3 millimeter spherical amorphous silica gel source. The crystal aggregates sizes can be tuned from 5 to 70 µm, depending on synthesis parameters, and the finished silicalite-1 aggregate particle takes the shape of the amorphous gel source. These aggregate particles, when containing a small amorphous core, should be suitable for packed adsorption column applications. Multiple hydrothermal synthesis experiments were performed by batch methods featuring silica gel spheres as the sole silica source for the batch. Zeolite nucleation and crystal growth were demonstrated throughout the amorphous bead. Synthesis parameters were optimized both for short synthesis times, optimal mechanical properties, and cost effectiveness. The influence of product crystal size on particle hardness was also investigated. The packing production process is sufficiently ready for supporting pilot scale adsorption studies.
|
3 |
Product distribution directed modification of ZSM-5 / Maretha FourieFourie, Maretha January 2012 (has links)
Ethylene and propylene are important chemical feedstocks for the production of polyethylene and polypropylene. Ethylene and propylene can be produced by various methods including steam cracking of liquefied natural gas (LNG), naphta or light olefin fractions. The methanol to olefin (MTO) process provides an alternative means of producing ethylene and propylene, where ZSM-5 is frequently used as catalyst due to its hydrophobicity, strong acidity, molecular sieve properties and low tendency towards coking, which makes ZSM-5 one the most popular zeolite catalysts in the industry. The oil crisis 1973 and the second oil crisis in 1978 caused the development of a commercial MTO process. Mobil Research and Development Corporation built a fixed-bed pilot plant to demonstrate the feasibility of the MTO as well as methanol-to-gasoline (MTG) process. When the oil price dropped again during the 1980’s, further developments of commercial processes were stopped for the time being. However, investigations on a bench scale are still pursued, and applications for patents are still submitted.
During this study ZSM-5 was synthesized with a hydrothermal method, which produced agglomerated polycrystalline grains with characteristic ZSM-5 morphology and a Si/Al ratio of approximately 40. The synthesis time, synthesis temperature and aging time were varied while keeping all the other synthesis parameters constant in order to determine their influence on crystallite size. The synthesis time was varied between 12-72 hours, synthesis temperature was varied between 130-170°C and aging time between 30-90 minutes. Using SEM to determine crystal size, it was found that a variation in the aging time produced the largest crystallites (average of 21.6μm ± 10.8μm) while also having the largest influence on crystallite size followed by synthesis temperature (average of 13.1μm ± 4.9μm) and finally synthesis time (average of 5.7μm ± 0.4μm). In all cases XRD and SEM confirmed the formation of ZSM-5.
To evaluate the as-synthesized ZSM-5 and compare it to a commercial ZSM-5 catalyst, Catalyst A using the MTO process, ZSM-5 was synthesized for 72 hours at 170°C with an aging time of 60 minutes before synthesis. The as-synthesized as well as Catalyst A’s agglomerated polycrystalline grains were sieved into three size fractions: smaller than 75μm, 75-150μm and 150-300μm. All six ZSM-5 fractions of ZSM-5 were used as catalysts for the MTO process in a fixed bed reactor at 400°C, atmospheric pressure and a 20wt% methanol to water feed. At 3.5 hours time on stream (TOS), the intermediate 75-150μm fraction had the highest light olefin selectivity for both the as-synthesized as well as Catalyst A, followed by the 150-300μm fraction and finally the smaller than 75μm fraction with the lowest light olefin selectivity. From this results it is clear that the as-synthesised ZSM-5 did not perform as well as Catalyst A.
While the intercrystalline voids of the agglomerated ZSM-5 form second-order pores where self-diffusion is enhanced, the increased diffusional barriers created by the intercrystalline boundaries reduce the diffusion rate, promoting secondary reactions at the strong Brönsted acid sites thereby reducing ethylene and propylene selectivity. Coking reduces access to the Brönsted acid sites and plays a more influencial role for smaller crystallite sizes. Accordingly, the smaller than 75μm fraction had the lowest light olefin selectivity, while the 150-300μm fraction was probably least influenced by coking. The increased pathways for products and reagents in the 150-300μm fraction resulted in more secondary reactions taking place within this catalyst than the 75-150μm fraction explaining the superior performance of the 75-150μm fraction. Since the grain size determines the ratio of the external to the internal surface areas as well as the amount of intercrystalline boundaries in the catalyst, it follows that the catalytic activity and polycrystalline grain size ratio should actually be tailored when optimising the product distribution of the ZSM-5 catalysed MTO process. The as-synthesized ZSM-5 didn’t perform very well when compared to Catalyst A and modification of the synthesis method is recommended. / Thesis (MSc (Chemistry))--North-West University, Potchefstroom Campus, 2012.
|
4 |
Product distribution directed modification of ZSM-5 / Maretha FourieFourie, Maretha January 2012 (has links)
Ethylene and propylene are important chemical feedstocks for the production of polyethylene and polypropylene. Ethylene and propylene can be produced by various methods including steam cracking of liquefied natural gas (LNG), naphta or light olefin fractions. The methanol to olefin (MTO) process provides an alternative means of producing ethylene and propylene, where ZSM-5 is frequently used as catalyst due to its hydrophobicity, strong acidity, molecular sieve properties and low tendency towards coking, which makes ZSM-5 one the most popular zeolite catalysts in the industry. The oil crisis 1973 and the second oil crisis in 1978 caused the development of a commercial MTO process. Mobil Research and Development Corporation built a fixed-bed pilot plant to demonstrate the feasibility of the MTO as well as methanol-to-gasoline (MTG) process. When the oil price dropped again during the 1980’s, further developments of commercial processes were stopped for the time being. However, investigations on a bench scale are still pursued, and applications for patents are still submitted.
During this study ZSM-5 was synthesized with a hydrothermal method, which produced agglomerated polycrystalline grains with characteristic ZSM-5 morphology and a Si/Al ratio of approximately 40. The synthesis time, synthesis temperature and aging time were varied while keeping all the other synthesis parameters constant in order to determine their influence on crystallite size. The synthesis time was varied between 12-72 hours, synthesis temperature was varied between 130-170°C and aging time between 30-90 minutes. Using SEM to determine crystal size, it was found that a variation in the aging time produced the largest crystallites (average of 21.6μm ± 10.8μm) while also having the largest influence on crystallite size followed by synthesis temperature (average of 13.1μm ± 4.9μm) and finally synthesis time (average of 5.7μm ± 0.4μm). In all cases XRD and SEM confirmed the formation of ZSM-5.
To evaluate the as-synthesized ZSM-5 and compare it to a commercial ZSM-5 catalyst, Catalyst A using the MTO process, ZSM-5 was synthesized for 72 hours at 170°C with an aging time of 60 minutes before synthesis. The as-synthesized as well as Catalyst A’s agglomerated polycrystalline grains were sieved into three size fractions: smaller than 75μm, 75-150μm and 150-300μm. All six ZSM-5 fractions of ZSM-5 were used as catalysts for the MTO process in a fixed bed reactor at 400°C, atmospheric pressure and a 20wt% methanol to water feed. At 3.5 hours time on stream (TOS), the intermediate 75-150μm fraction had the highest light olefin selectivity for both the as-synthesized as well as Catalyst A, followed by the 150-300μm fraction and finally the smaller than 75μm fraction with the lowest light olefin selectivity. From this results it is clear that the as-synthesised ZSM-5 did not perform as well as Catalyst A.
While the intercrystalline voids of the agglomerated ZSM-5 form second-order pores where self-diffusion is enhanced, the increased diffusional barriers created by the intercrystalline boundaries reduce the diffusion rate, promoting secondary reactions at the strong Brönsted acid sites thereby reducing ethylene and propylene selectivity. Coking reduces access to the Brönsted acid sites and plays a more influencial role for smaller crystallite sizes. Accordingly, the smaller than 75μm fraction had the lowest light olefin selectivity, while the 150-300μm fraction was probably least influenced by coking. The increased pathways for products and reagents in the 150-300μm fraction resulted in more secondary reactions taking place within this catalyst than the 75-150μm fraction explaining the superior performance of the 75-150μm fraction. Since the grain size determines the ratio of the external to the internal surface areas as well as the amount of intercrystalline boundaries in the catalyst, it follows that the catalytic activity and polycrystalline grain size ratio should actually be tailored when optimising the product distribution of the ZSM-5 catalysed MTO process. The as-synthesized ZSM-5 didn’t perform very well when compared to Catalyst A and modification of the synthesis method is recommended. / Thesis (MSc (Chemistry))--North-West University, Potchefstroom Campus, 2012.
|
5 |
Synthetic and atomic force microscopy studies of offretite/erionite family zeolitesHolmes, Amy Elizabeth January 2012 (has links)
Several members of the ABC-6 zeolite family, namely offretite, zeolite T, ZSM-34 and zeolite L, were synthesised with a view to studying the effect of synthetic parameters on the resulting crystal properties. A range of procedures for producing offretite and ZSM-34 were tested, and crystals with the optimal morphology, purity, crystallinity and size identified. A standard procedure for synthesising zeolite T was used, before the effect of systematically altering the cation concentration, Si/Al ratio and water content in the synthesis mixture was studied, and the optimal composition identified. Ex-situ AFM was used to study the morphology of the resulting crystals, as well as to determine information about surface features, such as the shape and height of terraces. This information could be used to infer the growth mechanism for each crystal. The AFM studies of zeolite L were compared with those of previous studies and found to agree. For offretite, zeolite T and ZSM-34, 1.2 nm high terraces elongated along the length of the {100} face of the crystals were observed. Where the crystals exhibited a micro-crystalline morphology without distinct faces HR-SEM was used to study their morphology and terracing. In-situ AFM was used to study the dissolution of the crystals in basic media. In each case the terraces were observed to dissolve primarily length-wise. The dissolution of terraces on zeolite T was considered in particular detail. The terrace height was measured during dissolution, and three distinct measurements were observed, 1.2, 0.8 and 0.2 nm. These heights were related to framework features. Lateral force AFM measurements were used to show the relationship between decreased terrace height and increased lateral deflection, indicating that dissolving areas of crystal exhibited increased tip-sample friction. The rate of dissolution of terraces on zeolite T was also considered. It was found that dissolution rate increased with increasing NaOH concentration, and with increasing tip-sample force in the AFM. These observations allowed order of reaction for the dissolution process of zeolite T to be estimated at 2.54. A magnesium substituted aluminophosphate ABC-6 family zeotype material, MgAPO-CJ60, was also synthesised and analysed. Solid-state NMR was used to determine the distribution of aluminium and phosphorous within the framework, which was found to be non-random.
|
6 |
Rationalize the synthesis of zeolite catalysts by understanding reaction mechanismLi, Chengeng 29 June 2020 (has links)
[EN] The present thesis focuses on the rationalization of the zeolite synthesis for
catalysis by understanding the nature of active sites and their microenvironments,
together with their influence on the mechanisms of catalyzed reactions.
In the first part of the thesis, efforts have been put on attempting to achieve the
regioselective locating of active sites in zeolite catalyst and, more specifically, on
tunning acid site locations in zeolite framework. The development of a zeolite
synthesis strategy and an indicator that can describe the aluminum distribution
in the zeolite framework is important to evaluate if the final objective has been
achieved. In this part, in order to evaluate aluminum distribution in MFI
framework, an indicator based on monomolecular and bimolecular mechanisms
of n-hexene catalytic cracking was proposed. First, several ZSM-5 samples were
synthesized, which have been reported in the literature to have different
aluminum distributions. These samples were characterized to be analogous in
physicochemical properties and, then, tested in the n-hexene cracking to justify
the usefulness of the indicator proposed in this work. Using 27Al MAS NMR,
the aluminum locations were proved to be different, which was also reflected by
the indicator in this thesis, justifying its applicability to evaluate aluminum
locations. Afterward, this indicator has been employed to check the zeolite
synthesis methodology that could potentially lead to different aluminum
distribution in zeolite frameworks. Then, a boron-assisted synthesis is proposed
considering that boron and aluminum may have competitive positioning in
ZSM-5 framework. Then, and by means of DFT calculations, we have studied
if the unit cell of MFI shows different stabilities when substituted by aluminum
and/or boron in different T positions. It has been found that boron location is
less favored when introduced in 10-ring channels of the MFI framework, while
aluminum shows no preference for positioning among all the T-sites. ZSM-5
samples with different Si/Al and Si/B were synthesized and their
physicochemical properties as well as the relative proportion of paired and
isolated states of aluminum was characterized. Characterization includes n-hexene cracking, for which the samples showed different preference toward
monomolecular and bimolecular reactions. Finally, once the materials were
proved to have different aluminum distribution, they were employed in
methanol-to-propene (MTP) reactions to show the influence of aluminum
distribution on an industry-relevant reaction where the spatial confinement has
an important impact. Indeed, the samples with aluminum preferentially
positioned in 10-ring channel favored more monomolecular cracking and less
bimolecular side reactions such as oligomerization and hydrogen transfer, giving
higher propene yield and lower amount of alkanes and aromatics.
The second part of the thesis focuses on rationalizing the synthesis of zeolites
with cavities for catalyzing “a priory” selected reaction. More specifically, zeolite
synthesis was carried out using OSDAs that mimic the transition state (TS) or a
relevant intermediate in the target reaction. Ethylbenzene production by
transalkylation between diethylbenzene and benzene was selected as the reaction
to be catalyzed. A potential reaction TS was established and a
diaryldimethylphosphonium OSDA was synthesized that mimicks the transition
state in the diaryl-mediated mechanism of transalkylation between benzene and
diethylbenzene. Then, the OSDA successfully led to the formation of the largepore zeolite ITQ-27. This ITQ-27 was tested in the reaction of transalkylation
between benzene and diethylbenzene. The catalytic performance of this material
was benchmarked to be superior than other commercially employed zeolites,
such as USY, mordenite or Beta with similar physicochemical properties.
Finally, Methanol to olefins (MTO) reaction was chosen as another target
catalytic system, where the reaction pathways are more complicated than
transalkylation between benzene and diethylbenzene but nevertheless they have
been well established in the literature. Thus, several OSDAs were synthesized
mimicking the intermediates and transition states of the paring pathway, which
produces more propene and butenes, which are highly demanded among all
products. The OSDAs led to formation of several cage-based small pore zeolites,
such as CHA, RTH and AEI. All the zeolites obtained were tested in MTO
reactions to evaluate their catalytic activity and gave high selectivity toward light
olefins, which appeared to selectively depend on the zeolite tested. The tendency of each structure toward certain product distributions was related to the reaction
mechanism by establishing a structure-reactivity correlation, when the
experiment results were combined with theoretical calculations. It is proposed
that different shape of the cavities stabilize different precursor intermediates
present in the paring or side-chain pathways and this indicates the reaction
preference between each pathway and therefore the product distributions. A
linear correlation was obtained between the shape of cavities and the C3
=
/C2
=
molar ratios being possible. In this way, ITQ-3 (ITE structure) was predicted
that should also give higher selectivity toward paring pathway, which has been
demonstrated experimentally / [ES] La presente tesis se centra en la racionalización de la síntesis de zeolitas para su
aplicación como catalizadores mediante la comprensión de la naturaleza de los
sitios activos y sus microambientes, junto con su influencia en los mecanismos
de las reacciones catalizadas.
En la primera parte de la tesis, se han realizado esfuerzos para intentar lograr la
ubicación regioselectiva de los sitios activos en el catalizador zeolítico y, más
específicamente, en la ubicación controlada de sitios ácidos en la red cristalina
de la zeolita. El desarrollo de una estrategia de síntesis adecuada junto con un
indicador que pueda describir la distribución de aluminio en la red de la zeolita
es importante para evaluar si se ha logrado el objetivo final. En esta parte, para
evaluar la distribución de aluminio en la red de la zeolita MFI, se ha propuesto
un indicador basado en los mecanismos monomoleculares y bimoleculares
asociados a la reacción de craqueo catalítico de n-hexeno. En primer lugar, se
sintetizaron varias muestras de ZSM-5, que según la literatura tienen diferentes
distribuciones de aluminio. Estas muestras se caracterizaron por ser análogas en
propiedades fisicoquímicas y, posteriormente, se analizaron en la reacción de
craqueo de n-hexeno para justificar la utilidad del indicador propuesto en este
trabajo. A partir de RMN MAS de 27Al se demostró que las ubicaciones de
aluminio eran diferentes, lo que también se reflejó en el indicador propuesto en
esta tesis, lo que justifica su aplicabilidad para evaluar distribuciones de aluminio.
Posteriormente, este indicador se ha empleado para verificar la nueva
metodología de síntesis de zeolitas que podría conducir a una distribución de
aluminio diferente en sus estructuras cristalinas. En este sentido, se propone la
síntesis de la zeolita ZSM-5 asistida por boro, considerando que el boro y el
aluminio podrían tener un posicionamiento competitivo en la estructura MFI.
Mediante cálculos de DFT, se ha estudiado si la celda unidad de MFI muestra
diferente estabilidad cuando se introduce aluminio y/o boro en diferentes
posiciones cristalográficas T. Se ha encontrado que la ubicación del boro está
menos favorecida cuando se introduce en los canales de 10 miembros de la estructura MFI, mientras que el aluminio no muestra preferencia por el
posicionamiento entre todos los sitios T. Se sintetizaron muestras de ZSM-5 con
diferentes Si/Al y Si/B y se caracterizaron sus propiedades fisicoquímicas, así
como la proporción relativa de estados emparejados y aislados de aluminio. La
caracterización incluye el craqueo de n-hexeno, para el cual las muestras
mostraron una preferencia diferente hacia las reacciones monomoleculares y
bimoleculares. Finalmente, una vez demostrada la distinta distribución de
aluminio en los materiales sintetizados, estos catalizadores se estudiaron en la
reaccióde metanol a propeno (MTP) para mostrar la influencia de la distribución
de aluminio en una reacción relevante a nivel industrial, donde el confinamiento
espacial tiene un impacto importante. De hecho, las muestras con aluminio
posicionadas preferentemente en un canal de 10 miembros favorecen reacciones
de craqueo monomolecular frente a reacciones secundarias bimoleculares, como
por ejemplo reacciones de oligomerización y de transferencia de hidrógeno,
dando un mayor rendimiento a propeno y una menor cantidad de alcanos y
compuestos aromáticos.
La segunda parte de la tesis se centra en racionalizar la síntesis de zeolitas con
cavidades para catalizar una reacción seleccionada "a priori". Más
específicamente, la síntesis de zeolita se llevó a cabo utilizando agentes directores
de estructura orgánicos (ADEO) que mimetizan el estado de transición (ET) o
el intermedio relevante en la reacción objetivo. La producción de etilbenceno
por transalquilación entre dietilbenceno y benceno se ha seleccionado como una
reacción objetivo a catalizar. Se estableció el ET determinante de la reacción y
se sintetizó un ADEO tipo diarildimetilfosfonio que mimetiza el estado de
transición del mecanismo de la reacción de transalquilación entre benceno y
dietilbenceno. Dicho ADEO permitió la cristalización de la zeolita de poro
grande ITQ-27, cuyo comportamiento catalítico se estudió en la reacción de
transalquilación entre benceno y dietilbenceno. La actividad catalítica de la
zeolita ITQ-27 se mostró claramente superior al de otras zeolitas empleadas
comercialmente, como USY, mordenita o Beta, todas ellas con propiedades
fisicoquímicas similares a la ITQ-27. Finalmente, la reacción de metanol a olefinas (MTO) se eligió como otro sistema
catalítico objetivo, donde los mecanismos de reacción son mucho más
complicados que en el caso de la reacción de transalquilación entre benceno y
dietilbenceno, pero, sin embargo, están bien establecidos en la literatura. Se
sintetizaron varios ADEOs que mimetizan los intermedios y los estados de
transición de la ruta “paring”, que produce más propeno y butenos, y que son
posiblemente los productos más demandados. Dichos ADEOs mímicos
permitieron la formación de varias zeolitas de poro pequeño basadas en
cavidades, como las zeolitas CHA, RTH y AEI. Todas las zeolitas obtenidas se
probaron en la reacción MTO para evaluar su actividad catalítica, obteniéndose
una alta selectividad hacia distintas olefinas ligeras, cuya selectividad depende de
la forma y tamaño de la cavidad de cada zeolita. La tendencia de cada estructura
hacia ciertas distribuciones de productos se ha relacionado con el mecanismo de
reacción, pudiendo establecer una correlación estructura-reactividad al combinar
los resultados experimentales con cálculos teóricos. / [CA] La present tesi es centra en la racionalització de la síntesi de zeolites per a la seva
aplicació com a catalitzadors mitjançant la comprensió de la naturalesa dels
centres actius i els seus microambientes, juntament amb la seva influència en els
mecanismes de les reaccions catalitzades.
A la primera part de la tesi, s'han realitzat esforços per intentar aconseguir la
ubicació regioselectiva dels centres actius en el catalitzador zeolític i, més
específicament, en la ubicació controlada de centres àcids en la xarxa cristal·lina
de la zeolita. El desenvolupament d'una estratègia de síntesi adequada juntament
amb un indicador que descriga la distribució d'alumini a la xarxa de la zeolita és
important per avaluar si s'ha aconseguit l'objectiu final. En aquesta part, per
avaluar la distribució d'alumini a la xarxa de la zeolita MFI, s'ha proposat un
indicador basat en els mecanismes monomoleculares i bimoleculars associats a
la reacció de craqueig catalític de n-hexé. En primer lloc, es van sintetitzar
diverses mostres de ZSM-5, que segons la literatura tenen diferents distribucions
d'alumini. Aquestes mostres es van caracteritzar per ser anàlogues en propietats
fisicoquímiques i, posteriorment, es van analitzar en la reacció de craqueig de nhexéper justificar la utilitat de l'indicador proposat en aquest treball. A partir
dels espectres de RMN MAS de 27Al es va demostrar que les ubicacions d'alumini
eren diferents, el que també es va reflectir en l'indicador proposat en aquesta tesi,
justificant la seva aplicabilitat per avaluar distintes distribucions d'alumini.
Posteriorment, aquest indicador s'ha emprat per verificar la nova metodologia
de síntesi de zeolites que podria conduir a una distribució d'alumini diferent al
llarg de les seves estructures cristal·lines. En aquest sentit, s’ha proposat la síntesi
de la zeolita ZSM-5 assistida per bor, considerant que el bor i l'alumini podrien
tenir un posicionament competitiu en l'estructura MFI. Mitjançant càlculs de
DFT, s'ha estudiat si la cel·la unitat de MFI mostra diferent estabilitat quan
s’introdueix alumini i/o bor en diferents posicions cristal·logràfiques T. S'ha
trobat que la ubicació dels àtoms de bor està menys afavorida als canals de 10
membres de la estructura MFI, mentre que l'alumini no mostra preferència pel
posicionament entre tots els llocs T. Es van sintetitzar mostres de ZSM-5 amb diferents relacions de Si/Al i Si/B i es van caracteritzar les seves propietats
fisicoquímiques, així com la proporció relativa d'estats aparellats i aïllats
d'alumini. La caracterització inclou la reacció de craqueig de n-hexé, on les
mostres van mostrar una preferència diferent cap a les reaccions
monomoleculares i bimoleculars. Finalment, un cop demostrada la diferent
distribució d'alumini en els materials sintetitzats, aquests catalitzadors es van
estudiar a la reacció de metanol a propè (MTP) per mostrar la influència de la
distribució d'alumini en una reacció rellevant a nivell industrial, on el
confinament espacial té un impacte important. De fet, les mostres amb alumini
posicionades preferentment en un canal de 10 membres afavoreixen reaccions
de craqueig monomolecular enfront de reaccions secundàries bimoleculars, com
ara reaccions d'oligomerització i de transferència d'hidrogen, donant un major
rendiment a propè i una menor quantitat d'alcans i compostos aromàtics.
La segona part de la tesi es centra en racionalitzar la síntesi de zeolites amb
cavitats per catalitzar una reacció seleccionada "a priori". Més específicament, la
síntesi de zeolita es va dur a terme utilitzant agents directors d'estructura orgànics
(ADEO) que mimetitzen l'estat de transició (ET) o l'intermedi rellevant en la
reacció objectiu. La producció de etilbenzèper transalquilació entre dietilbenzè
i benzè s'ha seleccionat com una reacció objectiu a catalitzar. Es va establir l'ET
determinant de la reacció i es va sintetitzar un ADEO tipus diarildimetilfosfoni
que mimetitza eixe estat de transició. Eixe ADEO va permetre la cristal·lització
de la zeolita de porus gran ITQ-27, i el seu comportament catalític es va estudiar
en la reacció de transalquilación entre benzè i dietilbenzè. L'activitat catalítica de
la zeolita ITQ-27 es va mostrar clarament superior a la d'altres zeolites emprades
comercialment, com la USY, mordenita o Beta, totes elles amb propietats
fisicoquímiques similars a la ITQ-27.
Finalment, la reacció de metanol a olefines (MTO) es va triar com un altre
sistema catalític objectiu, on els mecanismes de reacció són molt més complicats
que en el cas de la reacció de transalquilació entre benzè i dietilbenzè, però que,
al mateix temps, estan ben establerts en la literatura. Es van sintetitzar diversos
ADEOs que mimetitzen alguns dels intermedis i dels estats de transició de la
ruta "paring", que produeix més propè i butens, i que són possiblement els productes més demandats. Aquests ADEOs mímics van permetre la formació
de diverses zeolites de porus petit basades en cavitats, com les zeolites CHA,
RTH i AEI. Totes les zeolites obtingudes es van provar en la reacció MTO per
avaluar la seva activitat catalítica, obtenint una alta selectivitat cap a diferents
olefines lleugeres, on la selectivitat cap a cada olefina lleugera depèn de la forma
i mida de la cavitat de cada zeolita. La tendència de cada estructura cap a certes
distribucions de productes s'ha relacionat amb el mecanisme de reacció, i s´ha
pogut establir una correlació estructura-reactivitat al combinar els resultats
experimentals amb càlculs teòrics. / Li, C. (2020). Rationalize the synthesis of zeolite catalysts by understanding reaction mechanism [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/147115
|
7 |
Zeolites fit for a crownNearchou, Antony January 2019 (has links)
No description available.
|
8 |
The role of aluminium content in the control of the morphology of fly ash based hierarchical zeolite XCornelius, Mero-Lee Ursula January 2015 (has links)
>Magister Scientiae - MSc / Coal is the main source of electricity in South Africa, the combustion of which produces a large amount of waste (coal fly ash) annually. The large-scale generation of coal fly ash places major strain on landfills and the material is toxic in nature. The high silicon and aluminium content in fly ash makes it a suitable starting material for zeolite synthesis. Utilisation of fly ash as a starting material for zeolite synthesis alleviates an environmental burden by converting a waste product to an industrially applicable material. In this study, hierarchical zeolite X was synthesised from coal fly ash via the fusion method. The clear fused fly ash (FFA) extract (with molar composition 0.12 Al·14.6 Na·1.00 Si·163 H₂O) served as the synthesis solution for hydrothermal treatment. The influence of synthesis
parameters (such as Si/Al ratio, aluminium source, hydrothermal temperature and stirring) on hierarchical zeolite X formation was studied to determine the cause behind the formation of this material. Synthesised zeolites and starting materials (Arnot coal fly ash and fused fly ash) were characterised by various analytical techniques such as XRD and SEM-EDS to determine the phase purity, morphology and elemental composition (framework Si/Al ratio) of these materials. The synthesis of hierarchical zeolite X under hydrothermal conditions was found to be highly sensitive to the aluminium content of the synthesis solution. The hierarchical
morphology of zeolite X was formed preferentially in relatively aluminium-deficient (i.e. high Si/Al ratio) synthesis environments under stirred hydrothermal conditions of 90 °C for 16 hours. In the case of sodium aluminate addition, octahedral shaped zeolite X crystals were formed in relatively low Si/Al ratio synthesis environments, which was attributed to the presence of excess sodium cation content in the synthesis solution. Selected hierarchical zeolites (D2 and E2) were characterised further to gain more insight into the properties of this material. HR-TEM and FTIR revealed that hierarchical zeolite D2 and E2 exhibited the typical structural features of zeolite X. Zeolite D2 and E2 contained both micropores and mesopores and had a high BET surface area of 338-362 m²/g. These zeolites also exhibited appreciable solid acidity (0.81-1.12 mmol H/g zeolite). These properties make hierarchical zeolite X a favourable material for application in catalysis or adsorption. Overall, the formation of zeolite X with hierarchical morphology was proposed to be linked to the presence of zeolite P1 structural units in the framework of the zeolite. / National Research Foundation
|
9 |
Utiliza??o de rejeitos de Caulins na S?ntese de Ze?lita A / Use of tailings kaolins in Synthesis of Zeolite ASilva Filho, Severino Higino da 24 January 2014 (has links)
Made available in DSpace on 2014-12-17T15:42:15Z (GMT). No. of bitstreams: 1
SeverinoHSF_DISSERT.pdf: 1697537 bytes, checksum: d7338ec77a9bb83dfa28e39f146cdab3 (MD5)
Previous issue date: 2014-01-24 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / Three studies were performed using tailings kaolin for the synthesis of zeolite A. The first synthesis of zeolite A was performed using a kaolin waste generated from the beneficiation of kaolin for paper production process was studied. The kaolin waste was thermally activated at a temperature range of 550-800?C. For comparison was performed a synthesis pattern of Zeolite A(procedure IZA). The prepared materials were characterized by 27Al MAS NMR, X-ray diffraction and scanning electron microscopy with microprobe rays. The pre-tramento proved to be the most appropriate and suitable temperatures are between 600 and 700?C. Observed the formation of zeolite A in all materials, reaching 52% crystallinity, and the presence of phase sodalite and amorphous material. The second study was the use of a highly reactive metakaolin originating from the Jari region in the synthesis of zeolite A by a new method of hydrothermal synthesis. The zeolite is obtained pure and highly crystalline employing the Jari kaolin calcined at 600 ? C for 2h when the transformation to metakaolin occurs. Get to zeolite phase A at 4pm. The best crystallization time was of 24 h afforded a crystallinity of 67.9%. The third study was the evaluation of the NaOH / metakaolin and crystallization time on the synthesis of zeolite NaA from a sample of kaolin waste, named Kaolin Coverage. The experiments were performed using statistical design (axial points) and rejoinder the center point. The samples were characterized by X-ray diffraction (XRD), scanning microscopic analysis and chemical analysis using an EPMA microprobe. The results showed that a relationship exists between the amount of NaOH added and the crystallization time. The experiment performed using the lowest ratio NaOH / metakaolin (0.5) and shorter (4 h) produced an amorphous material. The increase ratio of NaOH / metakaolin and crystallization time leads to formation of a more crystalline NaA phase, but the presence of phase with sodalite as impurities / Tr?s estudos foram realizados empregando rejeitos de caulins para a s?ntese da ze?lita A. O primeiro a s?ntese da Ze?lita A foi realizada utilizando-se um rejeito de caulim, gerado a partir do processo de beneficiamento de caulim para produ??o de papel, foi estudada. O rejeito de caulim foi ativado termicamente em um intervalo de temperatura de 550 a 800?C. Para efeito de compara??o foi realizada uma s?ntese padr?o de Ze?lita A (procedimento da IZA). Os materiais preparados foram caracterizados por RMN-MAS de 27Al, difra??o de raios X e Microscopia eletr?nica de varredura com microsonda. O pr?-tramento mostrou-se necess?rio e as temperaturas mais adequadas foram entre 600 e 700?C. Observou-se a forma??o da ze?lita A em todos os materiais, alcan?ando-se 52% de cristalinidade, al?m da presen?a da fase sodalita e de material amorfo. O segundo estudo foi o emprego de um metacaulim altamente reativo origin?rio da regi?o do Jar? na s?ntese da Ze?lita A atrav?s de um novo m?todo de s?ntese hidrotermal. A zeolita A ? obtida pura e altamente cristalina empregando o caulim da regi?o do Jar? calcinado a 600?C por 2h quando ocorre a transforma??o para metacaulim. Obtem-se a fase zeolita A em 4h. O melhor tempo de cristaliza??o encontrado foi de 24 h que proporcionou uma cristalinidade de 67,9 %. E o terceiro estudo foi a avalia??o da rela??o de NaOH / metacaulim e tempo de cristaliza??o na s?ntese da ze?lita NaA a partir de uma amostra de rejeito de caulim, nomeado como Caulim de Cobertura. Os experimentos foram realizados utilizando planejamento estat?stico (com pontos axiais) e treplica do ponto central. As amostras obtidas foram caracterizadas por difra??o de Raios-X (DRX), an?lises microsc?picas de varredura e an?lise qu?mica utilizando-se uma microssonda EPMA. Os resultados mostraram que existe uma rela??o entre a quantidade de NaOH adicionado e o tempo de cristaliza??o. Os experimento realizados utilizando a mais baixa rela??o NaOH / metacaulim (0,5) e menor tempo (4 h) produziu um material amorfo. J? o aumento da rela??o NaOH /Metacaulim e o tempo de cristaliza??o leva a forma??o de uma fase NaA mais cristalina, mas com a presen?a da fase sodalita como impureza
|
10 |
Síntese da zeólita MCM-22 a partir de sistema reacional contendo sódio e potássio e desenvolvimento de catalisadores ácidos com topologia MWW modificada.QUINTELA, Paulo Henrique Leite. 16 April 2018 (has links)
Submitted by Dilene Paulo (dilene.fatima@ufcg.edu.br) on 2018-04-16T15:00:45Z
No. of bitstreams: 1
PAULO HENRIQUE LEITE QUINTELA - TESE (PPGEQ) 2016.pdf: 3975153 bytes, checksum: 257f1154ea4502e70913fe7937bf8a3f (MD5) / Made available in DSpace on 2018-04-16T15:00:45Z (GMT). No. of bitstreams: 1
PAULO HENRIQUE LEITE QUINTELA - TESE (PPGEQ) 2016.pdf: 3975153 bytes, checksum: 257f1154ea4502e70913fe7937bf8a3f (MD5)
Previous issue date: 2016 / Capes / A MCM-22 é uma zeólita com estrutura porosa identificada pelo código MWW, cuja cristalização ocorre mediante a formação de um precursor lamelar. Embora a síntese da MCM-22 tenha sido extensivamente investigada, alguns parâmetros importantes para sua obtenção ainda não foram sistematicamente estudados. Neste contexto, o presente trabalho teve como objetivos avaliar a influência da fonte de alumínio e da presença dos cátions sódio e potássio na mistura reacional sobre a cristalização da MCM-22 e desenvolver catalisadores ácidos com topologia MWW modificada a partir da dessilicação da MCM-22 e da deslaminação do precursor lamelar. O método hidrotérmico foi utilizado para sintetizar a referida zeólita, variando-se a fonte de alumínio (hidróxido de alumínio, aluminato de sódio e pseudoboemita) e a quantidade relativa de sódio e potássio presente na mistura reacional, em condições estáticas. O processo de dessilicação foi efetuado utilizando soluções de hidróxido de sódio com diferentes concentrações, enquanto a deslaminação foi realizada via intumescimento do precursor lamelar e posterior esfoliação por sonicação. A acidez dos catalisadores foi avaliada por dessorção termoprogramada de amônia. Os resultados de DRX revelaram que entre as fontes de alumínio utilizadas o hidróxido de alumínio foi mais eficaz para sintetizar a MCM-22 nas condições experimentais empregadas, e que a presença simultânea de sódio e potássio na mistura reacional aumentou a cristalinidade e a taxa de cristalização da zeólita,quando o potássio correspondeu a 45% do total de metais alcalinos em base molar. As micrografias das amostras de MCM-22 mostraram que a morfologia e o tamanho das partículas foram afetados pelas diferentes proporções entre sódio e potássio avaliadas. As análises de DRX, adsorção física de N2 e MEV dos materiais dessilicados e deslaminados evidenciaram a sensibilidade da topologia MWW a tratamentos alcalinos e que o processo de esfoliação das monocamadas do precursor lamelar não ocorreu de forma integral. Os catalisadores ácidos com estruturas modificadas pelos processos de dessilicação e deslaminação apresentaram menor acidez e sítios ácidos mais fracos quando comparados à MCM-22 sem alterações estruturais, sendo a maior redução observada para o catalisador parcialmente esfoliado. / MCM-22 is a zeolite with a porous structure identified by the MWW code, which crystallization occurs through the formation of a lamellar precursor. Although the MCM-22 synthesis has been extensively investigated, some important parameters for its preparation have not yet been systematically studied. In this context, the present work aimed to evaluate the influence of the aluminum source and the presence of sodium and potassium cations in the reaction mixture on the MCM-22 crystallization and develop acid catalysts with MWW topology modified by MCM-22 desilication and delamination of its lamellar precursor. The hydrothermal method was used to synthesize the said zeolite, varying the aluminum source (aluminum hydroxide, sodium aluminate, and pseudoboehmite) and the relative amount of sodium and potassium present in the reaction mixture, under static conditions. The desilication process was conducted using sodium hydroxide solutions with different concentrations, whereas delamination was performed by swelling of the lamellar precursor and subsequent exfoliation by sonication. The catalysts acidity were evaluated by ammonia thermal programmed desorption. The XRD results showed that among the aluminum sources used the aluminum hydroxide was more effective to synthesize MCM-22 under the experimental conditions employed, and that the simultaneous presence of sodium and potassium in the reaction mixture increased zeolite crystallinity and crystallization rate, when potassium corresponded to 45% of the total alkali metal on a molar basis. The micrographs of MCM-22 samples showed that the morphology and particle size were affected by the different ratios between sodium and potassium evaluated. The XRD, N2 physical adsorption and SEM analyses of the desilicated and delaminated materials evidenced the MWW topology sensitivity to alkaline treatments and that the lamellar precursor monolayers exfoliation process did not occur integrally. The acid catalysts with structures modified by desilication and delamination processes presented lower acidity and weaker acid sites compared to the MCM-22 without structural changes, with the greatest reduction being observed in the partially exfoliated catalyst.
|
Page generated in 0.0845 seconds