Crystal-Phase Engineering in Heterogeneous Catalysis

Zhao, Jian-Wen; Wang, Hong-Yue; Feng, Li; Zhu, Jin-Ze; Liu, Jin-Xun; Li, Wei-Xue

doi:10.1021/acs.chemrev.3c00402

Cited by 23 publications

(4 citation statements)

References 339 publications

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“…Additionally, amorphous phase materials are also vital metastable-phase materials, exhibiting the characteristics of long-range disordered arrangements with no close-packed plane, e.g., amorphous IrO 2 and RuO 2 . , However, the preparation of metastable-phase materials still poses significant challenges due to their inherent thermodynamic instability. Furthermore, the stringent conditions required for selective growth of metastable-phase metal oxides present a formidable obstacle, which greatly stimulates the research enthusiasm in developing facile synthetic methods. , …”

Section: Introductionmentioning

confidence: 99%

Metastable-Phase Two-Dimensional Metal Oxides for Advanced Electrocatalysis

Luo,

Jin,

Shao

2024

Chem. Mater.

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Electrocatalysis, such as water electrolysis and fuel cells, is the leading candidate for achieving carbon neutrality. The metastable-phase two-dimensional (2D) oxides enhance catalytic performances in electrocatalysis due to the joint advantages of the 2D structure and metastable-phase, which are regarded as some of the most advanced electrocatalytic materials, although they are still at an early stage of development for such materials. Herein, we summarize the properties of metastable-phase 2D metal oxides based on their singular structures first. Thereafter, the structure analysis is reviewed in detail over some representative nanomaterials, especially for metastable-phase 2D metal oxides materials. Subsequently, we particularly emphasize the applications of the representative materials. Finally, we discuss the major challenges and new opportunities in the emerging field of metastable-phase 2D metal oxides. The work will not only provide a comprehensive understanding over metastable-phase 2D metal oxides in structure and performance but also supply the guidance on designing electrocatalysts with excellent performance.

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Section: Introductionmentioning

confidence: 99%

Metastable-Phase Two-Dimensional Metal Oxides for Advanced Electrocatalysis

Luo,

Jin,

Shao

2024

Chem. Mater.

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“…Crystal phase engineering of nanomaterials stands as a crucial aspect of materials science that presents versatile applications in various fields such as semiconductors, magnetic materials, energy storage, optical and photonic materials, and catalysis. − The application of crystal phase engineering has held particular significance in recent years, notably in catalysis, where it has garnered substantial attention for enhancement of the performance of nanoparticle (NP) catalysts. A number of investigations have shown that crystal-phase engineering can be a promising approach to modulate the performance of catalysts by alteration of the electronic and geometric structures of catalyst surfaces . Cobalt catalysts are increasingly regarded as promising alternatives to noble metallic catalysts due to their efficiency, environmental friendliness, and high abundance on Earth .…”

Section: Introductionmentioning

confidence: 99%

“…A number of investigations have shown that crystal-phase engineering can be a promising approach to modulate the performance of catalysts by alteration of the electronic and geometric structures of catalyst surfaces. 6 Cobalt catalysts are increasingly regarded as promising alternatives to noble metallic catalysts due to their efficiency, environmental friendliness, and high abundance on Earth. 21 These catalysts have gained prominence, particularly in the Fischer–Tropsch synthesis within industrial applications, due to their commendable intrinsic activity at low temperatures.…”

Section: Introductionmentioning

confidence: 99%

Tuning the Selectivity of Catalytic Nitrile Hydrogenation with Phase-Controlled Co Nanoparticles Prepared by Hydrosilane-Assisted Method

Jiang,

Deng,

Kita

et al. 2024

J. Am. Chem. Soc.

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Cobalt (Co) is a promising candidate to replace noble metals in the hydrogenation process, which is widely employed in the chemical industry. Although the catalytic performance for this reaction has been considered to be significantly dependent on the Co crystal phase, no satisfactory systematic studies have been conducted, because it is difficult to synthesize metal nanoparticles that have different crystalline structures with similar sizes. Here we report a new method for the synthesis of cobalt nanoparticles using hydrosilane as a reducing agent (hydrosilane-assisted method). This new method uses 1,3-butanediol and propylene glycol to successfully prepare fcc and hcp cobalt nanoparticles, respectively. These two types of Co nanoparticles have similar sizes and surface areas. The hcp Co nanoparticles exhibit higher catalytic performance than fcc nanoparticles for the hydrogenation of benzonitrile under mild conditions. The present hcp Co catalyst is also effective for highly selective benzyl amine production from benzonitrile without ammonia addition, whereas many catalytic systems require ammonia addition for selective benzyl amine production. Mechanistic studies revealed that the fast formation of the primary amine and the prevention of condensation and secondary amine hydrogenation promote selective benzonitrile hydrogenation for benzylamine over hcp Co nanoparticles.

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“…Two-dimensional (2D) layered materials have become a hotspot in the field of materials science owing to their physical and chemical properties . Among them, a subset of 2D materials exhibit phase transitions triggered by environmental factors. , Transition metal dichalcogenides (TMDs) stand out in this subset, offering atomic-scale thickness, direct bandgaps, significant spin–orbit coupling, and notable electronic and mechanical properties.…”

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confidence: 99%

Phase-Engineered MoSe₂/CeO₂ Composites for Room-Temperature Gas Sensing with a Drastic Discrimination of NH₃ and TEA Gases

Singh,

Shin,

Moon

et al. 2024

ACS Sens.

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Detecting and distinguishing between hazardous gases with similar odors by using conventional sensor technology for safeguarding human health and ensuring food safety are significant challenges. Bulky, costly, and power-hungry devices, such as that used for gas chromatography−mass spectrometry (GC−MS), are widely employed for gas sensing. Using a single chemiresistive semiconductor or electric nose (e-nose) gas sensor to achieve this objective is difficult, mainly because of its selectivity issue. Thus, there is a need to develop new materials with tunable and versatile sensing characteristics. Phase engineering of twodimensional materials to better utilize their physiochemical properties has attracted considerable attention. Here, we show that MoSe 2 phase-transition/CeO 2 composites can be effectively used to distinguish ammonia (NH 3 ) and triethylamine (TEA) at room temperature. The phase transition of nanocomposite samples from semimetallic (1T) to semiconducting (2H) prepared at different synthesis temperatures is confirmed via X-ray photoelectron spectroscopy (XPS). A composite sensor in which the 2H phase of MoSe 2 is predominant lacks discrimination capability and is less responsive to NH 3 and TEA. An MoSe 2 /CeO 2 composite sensor with a higher 1T phase content exhibits high selectivity for NH 3 , whereas one with a higher 2H phase content (2H > 1T) shows more selective behavior toward TEA. For example, for 50% relative humidity, the MoSe 2 /CeO 2 sensor's signal changes from the baseline by 45% and 58% for 1 ppm of NH 3 and TEA, respectively, indicating a low limit of detection (LOD) of 70 and 160 ppb, respectively. The composites' superior sensing characteristics are mainly attributed to their large specific surface area, their numerous active sites, presence of defects, and the n-n type heterojunction between MoSe 2 and CeO 2 . The sensing mechanism is elucidated using Raman spectroscopy, XPS, and GC−MS results. Their phase-transition characteristics render MoSe 2 /CeO 2 sensors promising for use in distributed, low-cost, and room-temperature sensor networks, and they offer new opportunities for the development of integrated advanced smart sensing technologies for environmental and healthcare.

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Crystal-Phase Engineering in Heterogeneous Catalysis

Cited by 23 publications

References 339 publications

Metastable-Phase Two-Dimensional Metal Oxides for Advanced Electrocatalysis

Metastable-Phase Two-Dimensional Metal Oxides for Advanced Electrocatalysis

Tuning the Selectivity of Catalytic Nitrile Hydrogenation with Phase-Controlled Co Nanoparticles Prepared by Hydrosilane-Assisted Method

Phase-Engineered MoSe₂/CeO₂ Composites for Room-Temperature Gas Sensing with a Drastic Discrimination of NH₃ and TEA Gases

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Crystal-Phase Engineering in Heterogeneous Catalysis

Cited by 23 publications

References 339 publications

Metastable-Phase Two-Dimensional Metal Oxides for Advanced Electrocatalysis

Metastable-Phase Two-Dimensional Metal Oxides for Advanced Electrocatalysis

Tuning the Selectivity of Catalytic Nitrile Hydrogenation with Phase-Controlled Co Nanoparticles Prepared by Hydrosilane-Assisted Method

Phase-Engineered MoSe2/CeO2 Composites for Room-Temperature Gas Sensing with a Drastic Discrimination of NH3 and TEA Gases

Contact Info

Product

Resources

About

Phase-Engineered MoSe₂/CeO₂ Composites for Room-Temperature Gas Sensing with a Drastic Discrimination of NH₃ and TEA Gases