Attractive In Situ Self‐Reconstructed Hierarchical Gradient Structure of Metallic Glass for High Efficiency and Remarkable Stability in Catalytic Performance

Jia, Zhe; Wang, Qing; Sun, Ligang; Wang, Qi; Zhang, Lai-Chang; Wu, Ge; Luan, Junhua; Jiao, Zengbao; Wang, Anding; Liang, Shun-Xing; Gu, Meng; Lü, Jian

doi:10.1002/adfm.201807857

Cited by 85 publications

(50 citation statements)

References 45 publications

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“…As shown in Fig. 7f, the E a of the Fe-MGI catalyst in this work is 34.2 kJ mol −1 , a value lower than observed for crystalline alloys and comparable to those of MG catalysts [40]. After comparing the degradation efficiencies and k obs in MB dye solutions with or without the Fe-MGI catalyst, in the presence of different H 2 O 2 concentrations, dye concentrations, temperatures, and pH values, it can be concluded that Fe-MGI shows good catalytic properties for Fenton-like processes in acid solutions.…”

Section: Catalytic Propertiessupporting

confidence: 54%

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Excellent long-term reactivity of inhomogeneous nanoscale Fe-based metallic glass in wastewater purification

et al. 2019

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Metallic glasses (MGs) have attracted great attention in wastewater treatment because of their high reactivity arising from amorphous structure, large residual stress and high density of low coordination sites. However, the reactivity of MGs would gradually slow down with time due to the passivation of active sites by corrosion products, resulting in limited long-term reactivity, which is also an unsolved key issue for established crystalline zero valent iron (ZVI) technology. Here, such problems are successfully overcome by introducing nanoscale chemical inhomogeneities in Fe-based MG (Fe-MGI), which apparently contributes to local galvanic cell effect and accelerates electron transfer during degradation process. More importantly, the selective depletion of Fe 0 causes local volume shrinkage and crack formation, leading to self-peeling of precipitated corrosion products and reacted regions. Thereby fresh low coordination sites could be continuously provided, counteracting the mass transport and reactivity deteriorating problem. Consequently, Fe-MGI demonstrates excellent long-term reactivity and self-refreshing properties even in neutral solution. The present results provide not only a new candidate but also a new route of designing ZVI materials for wastewater treatment.

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Section: Catalytic Propertiessupporting

confidence: 54%

“…The durability of the present , temperature of 25°C. system is even more stable than those of the most recently reported Fe-MGs with excellent sustainability that can be reused about 35 times [40]. Therefore, Fe-MGI shows sustainable long-term high reactivity.…”

Section: Long-term Reactivitymentioning

confidence: 84%

Excellent long-term reactivity of inhomogeneous nanoscale Fe-based metallic glass in wastewater purification

et al. 2019

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“…Chemically complex catalytic materials have been the subject that attracts tremendous research interest in materials science and engineering. [ 1–3 ] By increasing the chemical complexity of modern catalytic materials, it has been shown that superior properties could be achieved for their use in a variety of important applications, such as wastewater remediation, [ 4–8 ] catalysis, [ 9,10 ] energy storage, [ 11 ] and fuel cells. [ 12 ] Recently, a similar design principle was proposed by metallurgists to enhance the chemical complexity of alloys through the synthesis of multi‐principal element alloys, also known as high entropy alloys (HEAs), [ 13,14 ] for enhanced mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

High Entropy Intermetallic–Oxide Core–Shell Nanostructure as Superb Oxygen Evolution Reaction Catalyst

Ding

Bian

Shuang

et al. 2020

Advanced Sustainable Systems

157

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properties could be achieved for their use in a variety of important applications, such as wastewater remediation, [4][5][6][7][8] catalysis, [9,10] energy storage, [11] and fuel cells. [12] Recently, a similar design principle was proposed by metallurgists to enhance the chemical complexity of alloys through the synthesis of multi-principal element alloys, also known as high entropy alloys (HEAs), [13,14] for enhanced mechanical properties. [13,15,16] In addition, some HEAs also show promising functional properties, such as super-paramagneticity and superconductivity. [17,18] Interestingly, it is noteworthy that most HEAs reported so far contain active transition metals, [19] such as Ni, Co, and Fe, which are commonly used for electrochemical catalysis; however, to our best knowledge, the research on HEAs for electrocatalysis is still rare.In the broad field of clean energy, it is critical to promote oxidation reaction and O 2 production in the state-of-the-art energy storage devices, such as fuel cells and metal oxygen batteries. However, the kinetics of such reactions, which is of a multistep process, [19] is usually sluggish; therefore, high performance electrochemically catalytic materials are in great need today to improve the efficiency of oxygen evolution Designing active, stable, yet low cost electrocatalysts for the oxygen evolution reaction (OER) is pivotal to the next generation energy storage technology. However, conventional OER catalysts are of low electrochemical efficiency while the state-of-the-art nanoparticle-based catalysts require mechanical supports, thereby limiting their wide deployment. Here, it is demonstrated that, due to the excellent corrosion resistance of the Fe-Co-Ni-Cr-Nb high entropy intermetallic Laves phase, fabricating a high entropy bulk porous nanostructure is possible by dealloying the corresponding eutectic alloy precursor. As a result, a core-shell nanostructure with amorphous high entropy oxide ultrathin films wrapped around the nanosized intermetallic ligaments is obtained, which together, exhibits an extraordinarily large active surface area, fast dynamics, and superb long-term durability, outperforming the existing alloy-and ceramic-based OER electrocatalysts. The outcome of the research suggests that the paradigm of "high entropy" design can be used to develop high performance catalytic materials.

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“…Unlike their crystalline counterparts, metallic glasses do not possess defects like grain boundaries and dislocations [1][2][3][4][5][6][7]. Therefore, they show specific mechanical, chemical and physical properties, such as high strength, high hardness and good corrosion resistance [1,4,[8][9][10][11]. As a consequence, metallic glasses are great functional and structural materials from a point of practical application.…”

Section: Introductionmentioning

confidence: 99%

Correlation between High Temperature Deformation and β Relaxation in LaCe-Based Metallic Glass

Chen

Qiao

2020

Materials

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High-temperature deformation around the glass transition temperature Tg and the dynamic mechanical behavior of La30Ce30Al15Co25 metallic glass were investigated. According to dynamic mechanical analysis (DMA) results, La30Ce30Al15Co25 metallic glass exhibits a pronounced slow β relaxation process. In parallel, strain-rate jump experiments around the glass transition temperature were performed in a wide range of strain rate ranges. The apparent viscosity shows a strong dependence on temperature and strain rate, which reflects the transition from non-Newtonian to Newtonian flow. At low strain or high temperature, a transition was observed from a non-Newtonian viscous flow to Newtonian viscous flow. It was found that the activation volume during plastic deformation of La30Ce30Al15Co25 metallic glass is higher than that of other metallic glasses. Higher values of activation volume in La30Ce30Al15Co25 metallic glass may be attributed to existence of a pronounced slow β relaxation. It is reasonable to conclude that slow β relaxation in La30Ce30Al15Co25 metallic glass corresponds to the “soft” regions (structural heterogeneities) in metallic glass.

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Attractive In Situ Self‐Reconstructed Hierarchical Gradient Structure of Metallic Glass for High Efficiency and Remarkable Stability in Catalytic Performance

Cited by 85 publications

References 45 publications

Excellent long-term reactivity of inhomogeneous nanoscale Fe-based metallic glass in wastewater purification

Excellent long-term reactivity of inhomogeneous nanoscale Fe-based metallic glass in wastewater purification

High Entropy Intermetallic–Oxide Core–Shell Nanostructure as Superb Oxygen Evolution Reaction Catalyst

Correlation between High Temperature Deformation and β Relaxation in LaCe-Based Metallic Glass

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