Toward Informed Design of Nanomaterials: A Mechanistic Analysis of Structure–Property–Function Relationships for Faceted Nanoscale Metal Oxides

Rudel, Holly E.; Lane, Mary Kate M.; Muhich, Christopher L.; Zimmerman, Julie

doi:10.1021/acsnano.0c08356

Cited by 44 publications

(33 citation statements)

References 281 publications

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“…To further reveal the dominant exposed facets of the prepared In 2 O 3 , HRTEM, and SAED were used to characterize the microstructure of In 2 O 3 . The lattice fringes and diffraction spots indicated that the dominant exposed facets of In 2 O 3 –P are {111} Ia 3̅ and {110} Ia 3̅ (Figure b), , while {012} R 3̅ c , and {110} R 3̅ c are the dominant facets in In 2 O 3 -L (Figure f), and {110} R 3̅ c is the major facet in In 2 O 3 -R (Figure j). Thus, the distinct morphologies and facet-exposures of the prepared In 2 O 3 could be summarized as In 2 O 3 –P presents in a crystal shape of a hexahedral plate with {111} Ia 3̅ and {110} Ia 3̅ facets exposure (Figure d), In 2 O 3 -L exhibits a flat hexagonal prism shape (further-developed In 2 O 3 laminas) with {110} R 3̅ c and {012} R 3̅ c facets exposure (Figure h), and In 2 O 3 -R grown as an oblique four-prism with {110} R 3̅ c facet as the only exposed facet (Figure l).…”

Section: Resultsmentioning

confidence: 99%

“…Rather than introducing foreign components, facet engineering could provide a simpler but effective approach to fine-tune the photocatalysts’ physicochemical properties. − Recently, facet engineering techniques have been applied in developing effective catalysts for pollution control and energy conversion . For instance, the photocatalytic degradation performance of methyl orange (MO) was distinct among the various facets of TiO 2 (e.g., {001}, {010}, and {101}), while {001} facets exhibited 1.79 and 3.22 times higher kinetic rate than that of the {010} and {101} facets, respectively .…”

Section: Introductionmentioning

confidence: 99%

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Molecular-Level Insights on the Facet-Dependent Degradation of Perfluorooctanoic Acid

Ding

Tan

Chen

et al. 2021

ACS Appl. Mater. Interfaces

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Perfluorooctanoic acid (PFOA) has raised significant health concerns due to its high ecotoxicological risks and difficulties in removal by conventional water treatment process. Previous studies have demonstrated that photocatalytic techniques exhibit great potential in PFOA removal. However, the underlying mechanism of the degradation process has not been fully understood, particularly the contribution of the facet effects of catalysts. In this study, a combination of experiments and firstprinciples calculations were conducted to shed light on the facet-dependence of the interfacial interactions and oxidation during the PFOA degradation process. We proved that the interfacial interaction was essential in initiating the hole-dominated degradation process, and the {110} R3̅ c facet of hexagonal In 2 O 3 features the strongest interaction with PFOA. The overall defluorination rate was mainly controlled by the hole-dominated oxidation processes under UV irradiation, which were further attributed to the electronic structures and reaction site distributions of different In 2 O 3 surfaces. This study provides molecular-level insights on the facetdependent PFOA catalytic degradation process, which can guide the rational design of photocatalysts to achieve superior decontamination efficiency.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Molecular-Level Insights on the Facet-Dependent Degradation of Perfluorooctanoic Acid

Ding

Tan

Chen

et al. 2021

ACS Appl. Mater. Interfaces

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“…The reactivity of Cu/CeO 2 catalysts in the CO oxidation reaction is dependent on the exposed facet of CeO 2 , [ 8 ] and the synergy between Cu and CeO 2 phases, which is related to the interfacial reactivity, presence of O vacancies, enhanced reducibility of CeO 2 , and easy interplay between interfacial redox pairs (Cu +2 /Cu +1 and Ce +4 /Ce +3 ). [ 9 ] Furthermore, the size, shape, and electronic state of Cu/CeO 2 nanoparticles allow modulating the SMSI effect that, in turn, influences on the reactivity in the CO oxidation reaction.…”

Section: Introductionmentioning

confidence: 99%

Reduction‐Driven 3D to 2D Transformation of Cu Nanoparticles

Matte

Thill

Lobato

et al. 2022

Small

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The interaction between metal and metal oxides at the nanoscale is of uttermost importance in several fields, thus its enhancement is highly desirable. In catalysis, the performance of the nanoparticles is dependent on a wide range of properties, including its shape that is commonly considered stable during the catalytic reaction. In this study, highly reducible CeO2‐x nanoparticles are synthesized aiming to provide Cu/CeO2‐x nanoparticles, which are classically active catalysts for the CO oxidation reaction. It is observed that the Cu nanoparticles shape changes during reduction treatment (prior to the CO oxidation reaction) from a nearly spherical 3D to a planar 2D shape, then enhances the Cu–CeO2‐x interaction. The spread of the Cu nanoparticles over the CeO2‐x surface during the reduction treatment occurs due to the minimization of the total system energy. The shape change is accompanied by migration of O atoms from CeO2 surface to the border of the Cu nanoparticles and the change from the Cu0 to Cu+1 state. The spreading of the Cu nanoparticles influences on the reactivity results toward the CO oxidation reaction since it changes the local atomic order around Cu atoms. The results show a timely contribution for enhancing the interaction between metal and metal oxide.

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“…In this regard, however, a critical question arises: Is it feasible to adjust the surface chemistry of earth-abundant but relatively inactive materials in order to exhibit similar or ever superior performance to that of NMs? On account to the enormous progress so far accomplished on nano-synthesis, surface/interface functionalization and catalyst promotion fields, the answer to this question is definitely yes, as recently demonstrated [11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27].…”

Section: Introductionmentioning

confidence: 99%

“…High intrinsic activity of interfacial sites However, it is well-known today-thanks to the huge progress in cutting-edge characterization techniques-that the individual characteristics of catalyst's counterparts can notably affect not only their own activity but also the interaction between them with great consequences in catalysis. More specifically, by adjusting the geometrical and electronic features of the different counterparts through suitable synthetic and promotional routes highly active materials are obtained [12][13][14][15][16][17][18][19]21,22,24,27,56,[62][63][64][65][66][67][68][69][70][71][72][73][74]. Table 1 depicts at a glance, the main physicochemical modifications that can be induced by adjusting each of the aforementioned parameters.…”

Section: Introductionmentioning

confidence: 99%

Facet-Dependent Reactivity of Ceria Nanoparticles Exemplified by CeO2-Based Transition Metal Catalysts: A Critical Review

Konsolakis

Lykaki

2021

Catalysts

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The rational design and fabrication of highly-active and cost-efficient catalytic materials constitutes the main research pillar in catalysis field. In this context, the fine-tuning of size and shape at the nanometer scale can exert an intense impact not only on the inherent reactivity of catalyst’s counterparts but also on their interfacial interactions; it can also opening up new horizons for the development of highly active and robust materials. The present critical review, focusing mainly on our recent advances on the topic, aims to highlight the pivotal role of shape engineering in catalysis, exemplified by noble metal-free, CeO2-based transition metal catalysts (TMs/CeO2). The underlying mechanism of facet-dependent reactivity is initially discussed. The main implications of ceria nanoparticles’ shape engineering (rods, cubes, and polyhedra) in catalysis are next discussed, on the ground of some of the most pertinent heterogeneous reactions, such as CO2 hydrogenation, CO oxidation, and N2O decomposition. It is clearly revealed that shape functionalization can remarkably affect the intrinsic features and in turn the reactivity of ceria nanoparticles. More importantly, by combining ceria nanoparticles (CeO2 NPs) of specific architecture with various transition metals (e.g., Cu, Fe, Co, and Ni) remarkably active multifunctional composites can be obtained due mainly to the synergistic metalceria interactions. From the practical point of view, novel catalyst formulations with similar or even superior reactivity to that of noble metals can be obtained by co-adjusting the shape and composition of mixed oxides, such as Cu/ceria nanorods for CO oxidation and Ni/ceria nanorods for CO2 hydrogenation. The conclusions derived could provide the design principles of earth-abundant metal oxide catalysts for various real-life environmental and energy applications.

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Toward Informed Design of Nanomaterials: A Mechanistic Analysis of Structure–Property–Function Relationships for Faceted Nanoscale Metal Oxides

Cited by 44 publications

References 281 publications

Molecular-Level Insights on the Facet-Dependent Degradation of Perfluorooctanoic Acid

Molecular-Level Insights on the Facet-Dependent Degradation of Perfluorooctanoic Acid

Reduction‐Driven 3D to 2D Transformation of Cu Nanoparticles

Facet-Dependent Reactivity of Ceria Nanoparticles Exemplified by CeO2-Based Transition Metal Catalysts: A Critical Review

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