Ceria–Zirconia Particles Wrapped in a 2D Carbon Envelope: Improved Low‐Temperature Oxygen Transfer and Oxidation Activity

Aneggi, Eleonora; Rico-Pérez, Verónica; Leitenburg, Carla de; Maschio, S.; Soler, Lluís; Llorca, Jordi; Trovarelli, Alessandro

doi:10.1002/anie.201507839

Cited by 53 publications

(53 citation statements)

References 23 publications

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“…However,m echanochemical activation has not only been used to prepare catalytic materials with properties that match those of heterogeneous catalysts made by conventional methods (e.g.s ol-gel method, co-precipitation, wetness impregnation, etc. ): [25] In numerous cases,b all milling has proven fundamental in designing and improving the interface of solid catalysts, [26] boosting their catalytic and redox behavior, [27] increasing their dispersion on the catalyst matrix surface, [28] enriching the mesoporosity of the solid material, [29] and tempering the thermal conditions required for the heterogeneous catalyst to perform. [26] Although the large majority of the catalysts synthesized by mechanochemistry have been tested in experiments with controlled microreactors,s uch as fixed-bed catalytic reactors, [24] there have been reports where the catalytic activity of the solid materials for reactions at the interface of solid-gas systems was assessed under the application of am echanical force.B elow,w ew ill discuss some of these recent examples,a lthough this is not acomprehensive list.…”

Section: Mechanosynthesis and Use Of Heterogeneous Catalysts With Balmentioning

confidence: 99%

Mechanochemistry of Gaseous Reactants

2019

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In recent years, the application of mechanical energy to chemical systems has repeatedly proven beneficial to facilitate chemical transformations in various areas in chemistry. Today, a systematic body of evidence indicates that mechanochemistry holds great promise to become a game‐changer in chemical synthesis. Not only does mechanochemistry permit access to products that are inaccessible by established means (e.g. purely thermal activation), mechanochemical reactions often outperform their solution‐based counterparts in terms of sustainability. Most mechanochemical reactions carried out by ball milling techniques involve transformations of solids and liquids, but the number of mechanochemical reactions with gaseous reactants is increasing. The aim of this Minireview is to provide an overview of recent chemical reactions involving gaseous samples by ball milling techniques and to highlight advances in ball milling technology for the safe handling of gaseous reagents. Examples of reactions proceeding at the interface of solid–/liquid–/gas–gas systems that led to significant improvements in reactivity or selectivity will also be highlighted.

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Section: Mechanosynthesis and Use Of Heterogeneous Catalysts With Balmentioning

confidence: 99%

Mechanochemistry of Gaseous Reactants

2019

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“…Theinformation gathered from HRTEM and XPS studies show that on PdCeM there is aunique arrangement of Pd and ceria that is not observed on samples prepared by conventional routes.T his arrangement is the result of an interaction between Pd and ceria promoted by mechanical milling and by the redox characteristics of the two components.W erecently reported that the milling of ceria with carbon soot results in the formation of aCeO 2 core wrapped in asoft carbon shell; [7] the nanoscale arrangement created by mixing was promoted by the different hardness of the two materials that helps the spreading of the softer carbon particles on the surface of ceria. This might explain why the core-shell structure observed here is obtained only when mixing Pd metal nanoparticles and ceria and not when harder materials like PdO and/or ZrO 2 are used (0.6 vs.4GPa for Pd metal and ceria, respectively, against 8f or zirconia [16] ).…”

Section: Angewandte Chemiementioning

confidence: 99%

“…[3] It is reported from experimental [3b, 4] and computational [5] studies that an enhanced Pd-ceria interaction can improve significantly the catalytic activity of these materials.Inparticular,the presence of Pd into the ceria lattice can lead to the formation of highly reactive Pd 2+/4+ sites that show lower methane activation barriers compared to isolated PdO x units.I nterestingly, differently from what happens on PdO x clusters,o nt hese ionic Pd species methane activation proceeds via hydrogen abstraction, ar oute that is potentially very important for methane utilization. [7] By combining the above mentioned approaches,w eu se ac ontrolled one-step dry milling procedure where Pd metal nanoparticles are put in contact with ceria particles to prepare am ethane oxidation catalyst that outperforms traditional Pd/CeO 2 owing to the unique structural arrangements that characterize metal/support interface at nanoscale.Furthermore,avoiding the use of Pd nitrate or chloride solution significantly reduces waste generation ensuring lower environmental impact. [6] More recently we also investigated the milling of CeO 2 -based materials with carbon, originating a2 Dc arbon layer, covering the ceria particles,a nd improving the interfacial redox exchange between the two materials.…”

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confidence: 99%

Outstanding Methane Oxidation Performance of Palladium‐Embedded Ceria Catalysts Prepared by a One‐Step Dry Ball‐Milling Method

et al. 2018

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By carefully mixing Pd metal nanoparticles with CeO polycrystalline powder under dry conditions, an unpredicted arrangement of the Pd-O-Ce interface is obtained in which an amorphous shell containing palladium species dissolved in ceria is covering a core of CeO particles. The robust contact that is generated at the nanoscale, along with mechanical forces generated during mixing, promotes the redox exchange between Pd and CeO and creates highly reactive and stable sites constituted by PdO embedded into CeO surface layers. This specific arrangement outperforms conventional Pd/CeO reference catalysts in methane oxidation by lowering light-off temperature by more than 50°C and boosting the reaction rate. The origin of the outstanding activity is traced to the structural properties of the interface, modified at the nanoscale by mechanochemical interaction.

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“…[24] Die meisten dieser festen Materialien wurden effektiv in der heterogenen Katalyse gasfçrmiger Substrate angewendet (wie z. [29,26] Obwohl die Mehrheit der mechanisch synthetisierten Katalysatoren in Experimenten mit kontrollierten Mikroreaktoren, wie Festbettreaktoren, [24] getestet wurden, gibt es Berichte,indenen die katalytische Aktivitätder festen Materialien unter Anwendung mechanischer Energie in Reaktionen an der Grenzfläche von Festkçrper-Gas-Systemen bewertet wurde.I mF olgenden werden wir einige dieser jüngsten Beispiele diskutieren, wobei die Liste nicht vollständig ist. Die mechanochemische Aktivierung wurde jedoch nicht nur zur Herstellung von katalytischen Materialien mit Eigenschaften, die denen von durch konventionelle Methoden (z.…”

Section: Mechanochemische Reaktionen Durch Kugelmahlenunclassified

“…hergestellten heterogenen Katalysatoren entsprechen, eingesetzt. [25] In vielen Fällen erwies sich Kugelmahlen als essentiell füre ine Verbesserung der Oberfläche eines festen Katalysators, [26] der Optimierung des katalytischen und des Redoxverhaltens, [27] der Erhçhung der Dispersion auf der Katalysatormatrixoberfläche, [28] die Steigerung der Mesoporositätd es Festkçrpers und die Milderung der thermischen Bedingungen, die der heterogene Katalysator zur Funktion bençtigt. [29,26] Obwohl die Mehrheit der mechanisch synthetisierten Katalysatoren in Experimenten mit kontrollierten Mikroreaktoren, wie Festbettreaktoren, [24] [31] Im Jahr 2011 verçffentlichten Mulas et al eine mechanochemische Hydrierung von Kohlenmonoxid an mechanochemisch dargestellten heterogenen Katalysatoren [Gl.…”

Section: Mechanochemische Reaktionen Durch Kugelmahlenunclassified

Mechanochemie gasförmiger Reaktanten

Bolm

Hernández

2019

Angewandte Chemie

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In den letzten Jahren hat sich die Anwendung von mechanischer Energie auf chemische Systeme wiederholt als vorteilhaft erwiesen, um chemische Umwandlungen in verschiedenen Gebieten der Chemie zu erleichtern. Eine Vielzahl von systematischen Studien belegt heute, dass die Mechanochemie vielversprechende Möglichkeiten eröffnet, die chemische Synthese zu verändern. Nicht nur allein die Fähigkeit, die Herstellung von Produkten zu ermöglichen, die durch bestehende Methoden, wie der reinen thermischen Aktivierung, unzugänglich sind, haben zu einer Anerkennung der Mechanochemie geführt. Man hat auch gemerkt, dass mechanochemische Reaktionen ihre nasschemischen Gegenstücke oft hinsichtlich der Nachhaltigkeit übertreffen. Intuitiv sind die meisten mechanochemischen Reaktionen, die durch Kugelmahlen ausgeführt werden, mit der Umwandlung von Festkörpern und Flüssigkeiten verknüpft. In den letzten Jahren hat allerdings die Anzahl mechanochemischer Reaktionen mit gasförmigen Reaktanten zugenommen. Das Ziel dieses Kurzaufsatzes ist es daher, einerseits einen Überblick über chemische Reaktionen zu geben, die den Gebrauch von gasförmigen Proben in Kugelmühlen beinhalten, und andererseits die Fortschritte der Technologien und Aufbauten der Kugelmühlen aufzuzeigen, die den sicheren Umgang mit gasförmigen Reagenzien unter mechanochemischen Bedingungen ermöglicht haben. Darüber hinaus werden Beispiele für Reaktionen aufgezeigt, die an der Grenzfläche Feststoff/Flüssigkeit/Gas–Gas stattfinden und zu einer signifikanten Verbesserung der Reaktivität oder Selektivität geführt haben. Letztendlich hoffen wir zukünftige Arbeiten anzuregen, um verbleibende Herausforderungen auf dem Gebiet der Mechanochemie anzugehen.

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Ceria–Zirconia Particles Wrapped in a 2D Carbon Envelope: Improved Low‐Temperature Oxygen Transfer and Oxidation Activity

Cited by 53 publications

References 23 publications

Mechanochemistry of Gaseous Reactants

Mechanochemistry of Gaseous Reactants

Outstanding Methane Oxidation Performance of Palladium‐Embedded Ceria Catalysts Prepared by a One‐Step Dry Ball‐Milling Method

Mechanochemie gasförmiger Reaktanten

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