Micron-Sized Single-Crystal-like CoAPO-5/Carbon Composites Leading to Hierarchical CoAPO-5 with Both Inter- and Intracrystalline Mesoporosity

Sánchez‐Sánchez, Manuel; Manjón-Sanz, Alicia; Dı́az, Isabel; Mayoral, Álvaro; Sastre, Enrique

doi:10.1021/cg4001768

Cited by 4 publications

(4 citation statements)

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“…Academic interest in the preparation of SAPO catalysts has predominately focused on tuning hydrothermal synthesis. ,− For example, variation of the components in the synthesis gel and crystallization conditions enables to tailor the type of framework and its composition, , the Si distribution (hence acidity), the crystal size, and the morphology of the resulting solid. Moreover, the inclusion of various metals, like Cu, Co, Mn, and Fe, in the synthesis gel leads to SAPO frameworks with redox properties. , Alternatively, during the past decade, various approaches were devised to tailor the hydrothermal synthesis protocol in order to obtain hierarchically structured SAPOs. − The latter is achieved by addition of organic porogens to the synthesis gel, which are subsequently removed by combustion. The resulting hierarchical SAPOs combine the intrinsic micropores with an auxiliary level of (meso)porosity, aiming at reducing access and diffusion limitations and subsequently enhancing their performance in catalyzed reactions.…”

Section: Introductionmentioning

confidence: 99%

Hierarchical Silicoaluminophosphates by Postsynthetic Modification: Influence of Topology, Composition, and Silicon Distribution

2014

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are exposed to various acid and base treatments aimed at mesopore formation and investigation of associated physicochemical modifications. SAPOs amorphize strongly in aqueous NaOH, requiring the use of organic bases (e.g., tetrapropylammonium hydroxide or diethylamine) to preserve the crystallinity during base treatment. In acid media (HCl, H 4 EDTA, and Na 2 H 2 EDTA), SAPO-11 remains fully crystalline, while SAPO-34 strongly amorphize. No clear influence of the framework topology is established. The high resistance in alkaline media and low stability in acid media of SAPO-34 is attributed to its relatively high silicon content. Base treatment of SAPOs leads predominately to the formation of intercrystalline porosity. Still, an up to 4-fold increase in external surface and pore volume in SAPO-11 are achieved. Besides the formation of secondary porosity, base treatment of SAPOs induces a variety of (correlated) physicochemical changes. For example, the silicon distribution clearly influences the dissolution behavior of SAPO-11 in alkaline media, as zeolitic-like Si-domains are more resistant than AlPO domains. As a result, base leaching is selective to phosphorus and leads, depending on the silicon distribution, to either aluminum or silicon enrichment. The resulting changes in bulk composition can be directly related to the secondary porosity, as the Si and Al enrichment takes place predominately on the external surface. Acidity characterization (TPD of ammonia and IR spectroscopy of pyridine or 2,6-di-tert-butylpyridine adsorbed) shows that base treatment of SAPO-11 slightly reduces the concentration of Brønsted sites, while the number of Lewis sites is substantially increased. Moreover, the amount of Brønsted acid sites associated with the external surface is largely enhanced. The behavior of zeotypes, that is, AlPOs, SAPOs, and zeolites, in acid and basic aqueous solutions is generalized, highlighting the role of charge balancing cations. Catalytic evaluation of SAPO-11 shows the potential of base-treated samples in the alkylation of benzyl alcohol with toluene.

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Section: Introductionmentioning

confidence: 99%

Hierarchical Silicoaluminophosphates by Postsynthetic Modification: Influence of Topology, Composition, and Silicon Distribution

2014

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“…In spite of the success of this method in the synthesis of nanocrystalline zeolites, it was not applied to AlPOs/MeAPOs systems during years, probably because the method requires starting from soluble sources, which is not common in synthesis of AlPOs and not easy to be implemented in so phase-unspecific systems. In this context, MCHA is a quite phase-specific system towards AlPO4-5/MeAPO-5 materials, and it easily directs the crystallization of these materials by changing conventional sources of Al, which are almost always insoluble solid, by the highly soluble-in-water source AlCl3•6H2O [191]. After that previous optimization, the reactants necessary to form CoAPO-5 were incorporated within the carbon matrix one by one through successive witness impregnation.…”

Section: Additional Mesoporogen Role Of Mchamentioning

confidence: 99%

“…showing a pencil-like crystal emerging from the host carbon matrix. Adapted with permission from [191].…”

Section: Additional Mesoporogen Role Of Mchamentioning

confidence: 99%