Smart Pd Catalyst with Improved Thermal Stability Supported on High-Surface-Area LaFeO<sub>3</sub> Prepared by Atomic Layer Deposition

Onn, Tzia Ming; Monai, Matteo; Dai, Sheng; Fonda, Emiliano; Montini, Tiziano; Pan, Xiaoqing; Graham, George W.; Fornasiero, Paolo; Gorte, Raymond J.

doi:10.1021/jacs.7b12900

Cited by 85 publications

(83 citation statements)

References 44 publications

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“…For many potentially interesting precursors, the ligands cannot be easily removed in this temperature range. An example of this occurred with the precursor used in a recent study to deposit La 2 O 3 , La(TMHD) 3 (Tris(2,2,6,6-tetramethyl-3,5-heptanedionato) lanthanum) [36][37][38]. The organic ligands on this molecule are not removed by water or O 2 at ALD conditions, and are oxidized by ozone only very slowly.…”

Section: Problems With Conventional Ald Approaches To Catalyst and Elmentioning

confidence: 99%

“…The ALD approach is also applicable to mixed oxides, such as for example CeO 2 -ZrO 2 mixed oxides, by alternating suitable Ce and Zr precursors during ALD cycles [73,85]. Although high surface area perovskites can be prepared by combustion synthesis [86,87], LaFeO 3 films with the perovskite structure were also prepared by ALD [38].…”

Section: Coated Surfaces For Enhanced Stabilitymentioning

confidence: 99%

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Atomic Layer Deposition on Porous Materials: Problems with Conventional Approaches to Catalyst and Fuel Cell Electrode Preparation

et al. 2018

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Atomic layer deposition (ALD) offers exciting possibilities for controlling the structure and composition of surfaces on the atomic scale in heterogeneous catalysts and solid oxide fuel cell (SOFC) electrodes. However, while ALD procedures and equipment are well developed for applications involving flat surfaces, the conditions required for ALD in porous materials with a large surface area need to be very different. The materials (e.g., rare earths and other functional oxides) that are of interest for catalytic applications will also be different. For flat surfaces, rapid cycling, enabled by high carrier-gas flow rates, is necessary in order to rapidly grow thicker films. By contrast, ALD films in porous materials rarely need to be more than 1 nm thick. The elimination of diffusion gradients, efficient use of precursors, and ligand removal with less reactive precursors are the major factors that need to be controlled. In this review, criteria will be outlined for the successful use of ALD in porous materials. Examples of opportunities for using ALD to modify heterogeneous catalysts and SOFC electrodes will be given.

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Section: Problems With Conventional Ald Approaches To Catalyst and Elmentioning

confidence: 99%

Section: Coated Surfaces For Enhanced Stabilitymentioning

confidence: 99%

Atomic Layer Deposition on Porous Materials: Problems with Conventional Approaches to Catalyst and Fuel Cell Electrode Preparation

et al. 2018

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“…Lanthanum‐based perovskites deposited using ALD have been studied extensively for different applications . Recently, ALD deposited Pd doped LaFeO 3 was studied as a smart catalyst which undergoes efficient redox cycling . ALD was instrumental because of its ability to deposit highly conformal layers on high surface area supports, such as porous structures (Figure B), thus opening new avenues for research and development in the field of thermo‐chemical splitting of CO 2.…”

Section: Perovskite‐based Applicationsmentioning

confidence: 99%

“…This is especially true when one seeks to elucidate mechanistic information of ALD perovskite films and to understand how certain parameters affect its growth and its properties. As the use of synchrotrons has been on the rise to characterize ALD thin films, there still lacks any meaningful number of papers on ALD perovskites . XAS is a sensitive, element specific technique that can be used to get local electronic and geometric structure information of materials, similar to EELS, however with several key advantages .…”

Section: Characterization Of Perovskite Thin Films: Insights On Perovmentioning

confidence: 99%

“…21 Recently, ALD deposited Pd doped LaFeO 3 was studied as a smart catalyst which undergoes efficient redox cycling. 22 instrumental because of its ability to deposit highly conformal layers on high surface area supports, such as porous structures ( Figure 5B), thus opening new avenues for research and development in the field of thermo-chemical splitting of CO 2. 23 There are still challenges with perovskites with regards to chemical stability and low enthalpies, which needs to be addressed.…”

Section: Optoelectronicsmentioning

confidence: 99%

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Atomic layer deposition of perovskites part 2: Designing next generation electronic applications

Afif

Dadlani

Burgmann

et al. 2019

Mat Design & Process Comms

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From part one, we learned that perovskites are interesting materials with tunable properties. Here, four current applications are elaborated on; high-κ dielectrics, piezoelectrics, optoelectronics, and solar to energy conversion devices. To start with, we discuss perovskite based dynamic random-access memory (DRAM) capacitors, where ALD strontium titanate (STO) of thickness 10 nm can achieve dielectric constants (k) of up to 146. Next, we discuss ALD perovskite piezoelectric-based device design of nanoelectromechanical systems (NEMS) and microelectromechanical systems (MEMS). There is a renewed interest in barium-based ternary compounds which have piezoelectric coefficients up to 500 pC/ N. We further explore ALD perovskitebased solar photovoltaics (PVs), where conformal and uniform layers of lead sulfide (PbS) absorbing layers allow deposition on large surfaces, facilitating perovskite architectures with conversion efficiency reaching 20%. Finally, we learn how lanthanumbased perovskites can replace cerium oxide, which is currently utilized for thermochemical processes for solar to energy conversion. Subsequently, we discuss different characterization techniques allowing us to deepen our understanding of process property relationships eventually leading to further performance enhancements. K E Y W O R D Satomic layer deposition, high-κ, interfacial growth, nucleation and growth, perovskites, piezoelectric, ultra-thin films | PEROVSKITE-BASED APPLICATIONSIn the first part of this two-part review, we developed a fundamental understanding of ALD deposition of perovskites, based on growth mechanisms, interfacial interactions, precursor chemistries, and energetics. Now, we review applications where the ALD deposition of perovskites have been leveraged.

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The effects of stoichiometry on the properties of exsolved Ni‐Fe alloy nanoparticles for dry methane reforming

et al. 2020

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The dry reforming of methane has received notable attention as a chemical process to convert natural gas into value-added chemicals and fuels. Ni-based exsolution catalysts using perovskite oxides supports have been used for their attractive sinterresistance and coke-resistance properties. The perovskite oxide in itself has unique defect chemistry that can be used to manipulate and control the properties of the catalyst nanoparticles exsolved on the surface, therefore influencing both the nanoparticle and support characteristics. In this study, the La:Fe ratio of Ni-doped LaFeO 3 was used to manipulate and control the properties of exsolved Ni-Fe alloy nanoparticles. The Ni-Fe nanoparticles consisted of different sizes ranging from 10 to 380 nm. Temperature programmed surface reaction studies along with materials characterization with SEM, STEM-HAADF, XRD, and BET showed that the Ni-Fe nanoparticles from different solid precursors have the same active sites for methane activation but differ in performance and stability because of size effects, metalsupport strength, composition and support basicity. A mechanism is proposed to decipher the merits of the Ni-Fe nanoparticles with the best activity, selectivity, and stability in this study.

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Smart Pd Catalyst with Improved Thermal Stability Supported on High-Surface-Area LaFeO₃ Prepared by Atomic Layer Deposition

Cited by 85 publications

References 44 publications

Atomic Layer Deposition on Porous Materials: Problems with Conventional Approaches to Catalyst and Fuel Cell Electrode Preparation

Atomic Layer Deposition on Porous Materials: Problems with Conventional Approaches to Catalyst and Fuel Cell Electrode Preparation

Atomic layer deposition of perovskites part 2: Designing next generation electronic applications

The effects of stoichiometry on the properties of exsolved Ni‐Fe alloy nanoparticles for dry methane reforming

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Smart Pd Catalyst with Improved Thermal Stability Supported on High-Surface-Area LaFeO3 Prepared by Atomic Layer Deposition

Cited by 85 publications

References 44 publications

Atomic Layer Deposition on Porous Materials: Problems with Conventional Approaches to Catalyst and Fuel Cell Electrode Preparation

Atomic Layer Deposition on Porous Materials: Problems with Conventional Approaches to Catalyst and Fuel Cell Electrode Preparation

Atomic layer deposition of perovskites part 2: Designing next generation electronic applications

The effects of stoichiometry on the properties of exsolved Ni‐Fe alloy nanoparticles for dry methane reforming

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Product

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Smart Pd Catalyst with Improved Thermal Stability Supported on High-Surface-Area LaFeO₃ Prepared by Atomic Layer Deposition