Your search keyword '"EXSOLUTION"' showing total 640 results

1. Photothermal activation of methane dry reforming on perovskite-supported Ni-catalysts: Impact of support composition and Ni loading method

Author

Osti, Andrea, Costa, Simone, Rizzato, Lorenzo, Senoner, Beatrice, and Glisenti, Antonella

Published

2025

2. Performance of LaFeO3 and La0.8Sr0.2FeO3 perovskites in Reverse Water-Gas Shift

Author

Sror, Gal, Vradman, Leonid, Landau, Miron V., and Herskowitz, Moti

Published

2025

3. Ni-doping strategy for perovskite anodes towards high-performance ammonia-fueled SOFCs

Author

Rahumi, Or, Yuferov, Yuliy, Meshi, Louisa, Maman, Nitzan, and Borodianskiy, Konstantin

Published

2025

4. Self-regenerating LaFeO3 perovskites with “tamed” Pt as robust catalysts for propylene and CO complete oxidation

Author

Li, Pingzhen, Zheng, Changlong, Zhang, Zhen, Liu, Wei, Wu, Xiaodong, and Liu, Shuang

Published

2025

5. Catalytic and electrocatalytic performance of Sr(Ti0.3Fe0.7Ru0.07)O3-δ for applications in solid oxide fuel cells supplied with ethanol steam reforming mixtures

Author

Donazzi, Alessandro, Schmauss, Travis A., and Barnett, Scott A.

Published

2022

6. The Effect of Alumina-Rich Spinel Exsolution on the Mechanical Property of Calcium Aluminate Cement-Bonded Corundum Castables.

Author

Hou, Qiqi, Zhang, Zhongzhuang, Zhao, Yaning, Ye, Kaiwei, Tian, Jiajia, Mu, Yuandong, He, Jian, and Ye, Guotian

Subjects

*CALCIUM aluminate, *SCANNING electron microscopy, *X-ray diffraction, *CORUNDUM, *GRAIN size

Abstract

This study investigates the effect of the exsolution behavior of alumina-rich spinel on the formation and distribution of CA6 (CaAl12O19) in corundum castables bonded with calcium aluminate cement. In this study, alumina-rich spinel is substituted for tabular corundum in the same proportions and grain size. The matrices after curing were analyzed by X-ray diffraction (XRD), scanning electron microscopy (SEM), and energy dispersive spectroscopy (EDS). The phase composition and microstructure of the matrices containing alumina-rich spinel were analyzed after firing at 1600 °C. These results showed that the addition of alumina-rich spinel significantly improved the mechanical strength of the castables. This improvement was attributed to the alumina produced by spinel exsolution during firing at 1600 °C, which reacted in situ with CA2 (CaAl4O7) to form CA6. CA6 connects the different particles and forms an interspersed interlocking structure within the spinel. The CA6-MA interspersed interlocking structure replaces part of the CA6-Al2O3 structure and significantly improves the mechanical strength of the castables. [ABSTRACT FROM AUTHOR]

Published

2025

7. Provenance and burial history tracking from quartzite hosted detrital garnet grains Delhi Supergroup of rocks, Firozpur-Jhirka ridge, India.

Author

Singh, Ujjwal Kr, Paul, Pritam P., and Chakraborty, Partha Pratim

Subjects

*ELECTRON probe microanalysis, *RECRYSTALLIZATION (Geology), *GOETHITE, *MAGNETITE, *QUARTZITE, *GARNET

Abstract

Quartzites of the Delhi Supergroup, exposed along the Firozpur-Jhirka ridge in Faridabad, Gurgaon areas of Delhi-National Capital Area, host detrital garnet grains. The garnet grains are studied for understanding provenance and diagenetic history. Samples were collected from the Badkhal lake area, Faridabad. X-ray diffraction study identifies quartz, garnet, magnetite and goethite as major mineral phases. Whereas quartzites show recrystallization texture, garnet grains record intense fractures and magnetites form large acicular grains. From electron probe microanalysis garnet grains are identified as almandine with high spessartine content and a pegmatite source is suggested. From preserved in-situ exsolution of magnetite from garnet it is inferred that a temperature exceeding 550°C (>17 km burial depth) in the course of burial history and magnetites exsolved below 550°C from garnet during the uplift of quartzite. [ABSTRACT FROM AUTHOR]

Published

2024

8. The effect of the alumina-rich spinel exsolution on the microstructure of CAC-bonded castables.

Author

Zhang, Zhongzhuang, Hou, Qiqi, Zhao, Yaning, Zeng, Jinyan, Mu, Yuandong, He, Jian, Luo, Zhongtao, and Ye, Guotian

Subjects

*CALCIUM aluminate, *SPINEL, *PHASE diagrams, *HEAT treatment, *CORUNDUM

Abstract

According to the magnesia-alumina phase diagram, the alumina-rich spinel may undergo exsolution of corundum during firing when incorporated into the castable. This research aimed to explore the phenomenon of alumina-rich spinel exsolution and its subsequent impact on the distribution of CaO·6Al 2 O 3 inside the spinel and the strength of the castables when subjected to a firing temperature of 1600 °C. The results indicated that the amount of exsolved corundum escalated as the alumina content within the spinel rose after heat treatment, and this exsolved corundum was predominantly found within the original spinel particle. The CaO·2Al 2 O 3 , which formed when calcium aluminate cement was heated above 1200 °C, reacted preferentially with the exsolved corundum rather than with pre-added α-Al 2 O 3 leading to the formation of CaO·6Al 2 O 3 inside the spinel after firing at temperatures exceeding 1400 °C. This reaction formed an interpenetrated "spinel-CaO·6Al 2 O 3 " structure during firing, which enhanced the strength of the castables. [ABSTRACT FROM AUTHOR]

Published

2024

9. Forming Ni-Fe and Co-Fe Bimetallic Structures on SrTiO3-Based SOFC Anode Candidates

Author

Kinga Kujawska, Wojciech Koliński, and Beata Bochentyn

Subjects

solid oxide fuel cell, anode, exsolution, topotactic ion exchange, strontium titanate, catalytic activity, Fuel, TP315-360

Abstract

The aim of this work was to verify the possibility of forming Ni-Fe and Co-Fe alloys via topotactic ion exchange exsolution in Fe-infiltrated (La,Sr,Ce)0.9(Ni,Ti)O3-δ or (La,Sr,Ce)0.9(Co,Ti)O3-δ ceramics. For this purpose, samples were synthesized using the Pechini method and then infiltrated with an iron nitrate solution. The reduction process in dry H2 forced the topotactic ion exchange exsolution, leading to the formation of additional round-shape structures on the surfaces of grains. EDS scans and XRD analysis confirmed the formation of bimetallic alloys, which suggests that these materials have great potential for further use as anode materials for Solid Oxide Fuel Cells (SOFCs).

Published

2024

10. Synergistic Vertical Graphene‐Exsolved Perovskite to Boost Reaction Kinetics for Flexible Zinc–Air Batteries.

Author

Du, Juwei, Zhang, Nan, Zhang, Wenyu, Shi, Xiaojun, Gong, Yansheng, Wang, Rui, Wang, Huanwen, Jin, Jun, Zhao, Ling, and He, Beibei

Subjects

*CHEMICAL kinetics, *CHEMICAL vapor deposition, *OXYGEN evolution reactions, *FLEXIBLE electronics, *ACTIVATION energy, *LITHIUM-air batteries

Abstract

Zinc–air batteries (ZABs) hold significant promise for flexible electronics due to their high energy density and low cost. However, their practical application is hindered by the sluggish kinetics of the oxygen evolution and oxygen reduction reactions (OER/ORR). This study highlights a novel design of vertical graphene arrays (VGs) anchored on PrBa0.5Sr0.5Co1.8Ru0.2O5+δ (PBSCRu) perovskite nanofibers, fabricated via plasma‐enhanced chemical vapor deposition. Notably, the VG growth induces the exsolution of Co nanoparticles from the PBSCRu perovskite, resulting in a unique PBSCRu‐Co‐VG heterostructure. Theoretical calculations demonstrate that constructing PBSCRu‐Co‐VG heterojunction regulates interfacial electronic redistribution, thereby lowering energy barriers for both OER and ORR. As a result, the PBSCRu@VG‐5 electrocatalyst exhibits superior stability and higher peak power density in both liquid and flexible solid‐state ZABs compared to the pristine PBSCRu electrocatalyst. This protocol advances the integration of synergetic perovskite/metal/graphene composites, offering considerable potential for next‐generation energy conversion technologies. [ABSTRACT FROM AUTHOR]

Published

2024

11. An Angstrom‐Scale Protective Skin Grown In Situ on Perovskite Oxide to Enhance Stability in Water.

Author

Zhou, Α‐Wanglin, Xu, Fang, Tan, Jinkun, Liu, Zhengkun, Zhang, Guangru, Xu, Zhi, Lyu, Yinong, and Jin, Wanqin

Subjects

*TRANSMISSION electron microscopes, *CATALYST structure, *HYDROGEN evolution reactions, *PHASE transitions, *INTERFACE stability

Abstract

The utilization of perovskite oxide as a catalyst for aqueous reactions is promising but challenging in stability. Here, we propose an in situ growth strategy that constructs an ultrathin protective skin on the Sr0.9Fe0.81Ta0.09Ni0.1O3‐δ perovskite surface and thus effectively solves the stability issue. Using a spherical aberration‐corrected transmission electron microscope, we observe the coexistence of an angstrom‐scale (~7 Å) Fe2O3 protective skin and FeNi alloy nanoparticles. A number of alloy nanoparticles grow along with the skin and uniformly take root on the skin surface. Such a hierarchical structure can reconstruct the surface electronic structure and suppress the ion leaching of perovskite oxide in water. Benefiting from this unique structure, the catalyst has experienced a substantial increase (800 h, more than three orders of magnitude) in its stable operation time in water (for example, in a hydrogen evolution reaction). These results provide valuable insight into solid‐solid phase transitions and have substantial implications for using structural defects at surfaces to modulate mass transport and transformation kinetics. Our strategy is sufficiently simple and can be used to subtly manipulate the catalyst structures to improve the performance of perovskite‐based catalysts and potentially other oxide catalysts for a wide range of reactions. [ABSTRACT FROM AUTHOR]

Published

2024

12. 析出型纳米颗粒 SOFC 稀土钙钛矿阳极催化材料研究进展.

Author

刘思成, 宗鹏飞, 王仲尧, and 王 琦

Abstract

Copyright of Journal of the Chinese Society of Rare Earths is the property of Editorial Department of Journal of the Chinese Society of Rare Earths and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

13. Dielectric Barrier Plasma Discharge Exsolution of Nanoparticles at Room Temperature and Atmospheric Pressure.

Author

ul Haq, Atta, Fanelli, Fiorenza, Bekris, Leonidas, Martin, Alex Martinez, Lee, Steve, Khalid, Hessan, Savaniu, Cristian D., Kousi, Kalliopi, Metcalfe, Ian S., Irvine, John T. S., Maguire, Paul, Papaioannou, Evangelos I., and Mariotti, Davide

Subjects

*ATMOSPHERIC pressure plasmas, *SYNTHESIS gas, *ATMOSPHERIC temperature, *METAL nanoparticles, *ATMOSPHERIC pressure, *METHANATION

Abstract

Exsolution of metal nanoparticles (NPs) on perovskite oxides has been demonstrated as a reliable strategy for producing catalyst‐support systems. Conventional exsolution requires high temperatures for long periods of time, limiting the selection of support materials. Plasma direct exsolution is reported at room temperature and atmospheric pressure of Ni NPs from a model A‐site deficient perovskite oxide (La0.43Ca0.37Ni0.06Ti0.94O2.955). Plasma exsolution is carried out within minutes (up to 15 min) using a dielectric barrier discharge configuration both with He‐only gas as well as with He/H2 gas mixtures, yielding small NPs (<30 nm diameter). To prove the practical utility of exsolved NPs, various experiments aimed at assessing their catalytic performance for methanation from synthesis gas, CO, and CH4 oxidation are carried out. Low‐temperature and atmospheric pressure plasma exsolution are successfully demonstrated and suggest that this approach could contribute to the practical deployment of exsolution‐based stable catalyst systems. [ABSTRACT FROM AUTHOR]

Published

2024

14. Exsolved NiRu bimetallic nanoparticles induced by Ru doping in LaBaMn1.6Ni0.3Ru0.1O5+δ as a coking resistant anode catalyst layer for direct-methane solid oxide fuel cells.

Author

Zhang, Wei, Wei, Jialu, Zhu, Jiafeng, and Sun, Chunwen

Subjects

*STEAM reforming, *METHANE as fuel, *SOLID oxide fuel cells, *SYNTHESIS gas, *COKE (Coal product), *RUTHENIUM, *BIMETALLIC catalysts, *RUTHENIUM catalysts

Abstract

Due to its abundant resources and advantages in transportation and storage, methane fueled solid oxide fuel cells (SOFCs) are highly needed. In this work, an exceptional internal reforming catalyst comprising in-situ exsolved NiRu bimetallic nanoparticles and oxygen-deficient layered double perovskite LaBaMn 1.6 Ni 0.3 Ru 0.1 O 5+δ (r-LBMNR) was prepared. Compared to the cell with LaBaMn 1.6 Ni 0.4 O 5+δ (r-LBMN) catalyst, the cell with a Ru-doping r-LBMNR catalyst layer, exhibits superior peak power output of 336 mW cm−2 and better durability with a less decay rate of 0.014% per hour in CH 4 fuel. The enhanced electrochemical performance can be attributed to the high oxygen ion and electron conductivities of the catalyst and the coupling of Ni and Ru sites with the oxygen-deficient r-LBMNR matrix This coupling activates CH 4 and H 2 O, promotes the oxidation of C atoms in CH 4 molecules, and enables reversible hydrogen spillover, ultimately leading to the production syngas of CO(g) and H 2 (g). [Display omitted] • Trace Ru-doping facilitating the exsolution of nanoparticles. • LaBaMn 1.6 Ni 0.3 Ru 0.1 O 5+δ was modified with abundant O v and exsolved NiRu alloy. • Cell can operate stably over 220 h with a degradation rate of 0.014% h−1. [ABSTRACT FROM AUTHOR]

Published

2024

15. Forming Ni-Fe and Co-Fe Bimetallic Structures on SrTiO 3 -Based SOFC Anode Candidates.

Author

Kujawska, Kinga, Koliński, Wojciech, and Bochentyn, Beata

Subjects

SOLID oxide fuel cells, STRONTIUM titanate, CRYSTAL structure, NICKEL alloys, ANODES

Abstract

The aim of this work was to verify the possibility of forming Ni-Fe and Co-Fe alloys via topotactic ion exchange exsolution in Fe-infiltrated (La,Sr,Ce)0.9(Ni,Ti)O3-δ or (La,Sr,Ce)0.9(Co,Ti)O3-δ ceramics. For this purpose, samples were synthesized using the Pechini method and then infiltrated with an iron nitrate solution. The reduction process in dry H2 forced the topotactic ion exchange exsolution, leading to the formation of additional round-shape structures on the surfaces of grains. EDS scans and XRD analysis confirmed the formation of bimetallic alloys, which suggests that these materials have great potential for further use as anode materials for Solid Oxide Fuel Cells (SOFCs). [ABSTRACT FROM AUTHOR]

Published

2024

16. Metal–Perovskite Interfacial Engineering to Boost Activity in Heterogeneous Catalysis

Author

Christoph Malleier and Simon Penner

Subjects

perovskites, exsolution, structure-activity correlation, bi-functional synergism, Physics, QC1-999

Abstract

In this review, we have assessed the possibility of metal–perovskite interfacial engineering to enhance the catalytic activity and selectivity in a range of heterogeneous catalytic reactions. We embarked on a literature screening of different perovskite material classes and reactions to show the versatility of the perovskite structures to induce the formation of such hetero-interfaces and the widespread nature of the phenomenon in catalytic research. There is almost no limitation on the chemical composition of the used perovskites and the nature of the catalyzed reaction, be it under reduction or oxidation conditions. We attempted to classify the perovskite materials, discuss the different strategies leading to the hetero-interfaces, and detail the synergistic action of the components of the respective interfaces. We also provide a critical assessment of the large body of data that is available in terms of a knowledge-based approach to the comparison of differently prepared interfaces with varying interfacial extent to gain a deeper understanding of the bi-functional operation of the interfaces and the urgent necessity to study and characterize such interfaces under realistic operation conditions.

Published

2024

17. Recent Advances in Iridium‐based Electrocatalysts for Acidic Electrolyte Oxidation.

Author

Li, Wanqing, Bu, Yunfei, Ge, Xinlei, Li, Feng, Han, Gao‐Feng, and Baek, Jong‐Beom

Subjects

ELECTROCATALYSTS, OXYGEN evolution reactions, ENERGY conversion, IRIDIUM oxide, ELECTROLYTES, CORROSION resistance, ELECTROLYSIS

Abstract

Ongoing research to develop advanced electrocatalysts for the oxygen evolution reaction (OER) is needed to address demand for efficient energy conversion and carbon‐free energy sources. In the OER process, acidic electrolytes have higher proton concentration and faster response than alkaline ones, but their harsh strongly acidic environment requires catalysts with greater corrosion and oxidation resistance. At present, iridium oxide (IrO2) with its strong stability and excellent catalytic performance is the catalyst of choice for the anode side of commercial PEM electrolysis cells. However, the scarcity and high cost of iridium (Ir) and the unsatisfactory activity of IrO2 hinder industrial scale application and the sustainable development of acidic OER catalytic technology. This highlights the importance of further research on acidic Ir‐based OER catalysts. In this review, recent advances in Ir‐based acidic OER electrocatalysts are summarized, including fundamental understanding of the acidic OER mechanism, recent insights into the stability of acidic OER catalysts, highly efficient Ir‐based electrocatalysts, and common strategies for optimizing Ir‐based catalysts. The future challenges and prospects of developing highly effective Ir‐based catalysts are also discussed. [ABSTRACT FROM AUTHOR]

Published

2024

18. A Proposed Model for Cryovolcanic Activity on Enceladus Driven by Volatile Exsolution.

Author

Mitchell, Karl L., Rabinovitch, Jason, Scamardella, Jonathan C., and Cable, Morgan L.

Subjects

CHEMICAL processes, DYNAMIC pressure, FLUID mechanics, GEYSERS, PHYSICS, EXPLOSIVE volcanic eruptions

Abstract

There is considerable interest in sending a mission to Enceladus to sample its erupting materials, which are sourced from its ocean, a proposed habitable environment. However, we lack resolution between competing ascent and eruption models, which offer differing consequences and challenges for mission sampling and access strategies. We report a new Enceladus ascent and eruption model, "Cryo‐Erupt," where ascent from ocean to jet is driven by the exsolution and expansion of dissolved gases from ascending water within conduits. This mechanism shares many similarities with some forms of terrestrial activity, including explosive silicate volcanism, cold‐water geysers and "limnic" eruptions. This preliminary study suggests that this mode of ascent and eruption is viable and broadly consistent with a range of observations including the apparent co‐existence of point‐ (jet) and fissure‐ (curtain) sourced activity as well as strong contrasts in velocity and ice‐to‐vapor ratio between the plume and the jets feeding it. However, it requires the co‐existence of a sublimation plume as an additive component to the broader plume. The outcomes of the Cryo‐Erupt model differ in terms of conduit physical and chemical processes from previously proposed boiling interface eruption models, for example, predicting larger dynamic pressures and narrower conduits, which could present challenges for direct robotic access. Due to the lack of a static boiling interface or wall condensation, bulk composition is unlikely to change appreciably during ascent from the ocean‐conduit interface to the jet, potentially simplifying the interpretation of samples collected in space or on Enceladus' surface. Plain Language Summary: High‐speed jets from giant ice fissures on Saturn's moon Enceladus feed a large plume, which is of interest to scientists because it contains salts and organic compounds, which are evidence of a subsurface ocean that may possibly host life. However, it is unclear how the chemistry of the plume material (gas and grains) might be altered as this material moves from the ocean into space, and to what extent samples from the plume are representative of ocean composition. Previous models to predict this behavior mostly relied on boiling of water as the primary way that gas and droplets are ejected, but these models do not take into account all of the physics involved, and do not fully reproduce what Cassini observed at Enceladus. We propose a new model that instead invokes dissolved gas molecules expanding, similar to explosive volcanoes on Earth and essentially the same mechanism that causes cans of soda to explode upon opening if shaken. We predict that the erupting jets would largely preserve bulk ocean content and thus would be the best place to study ocean content, in contrast with the broader plume, which would have more water that has sublimated from the surface. Key Points: Recent studies on the ascent and eruption of Enceladus' plume have neglected the role of exsolution and expansion of dissolved volatilesVolatile‐driven direct ocean‐to‐jet liquid water ascent is generally consistent with observations if combined with a sublimation co‐plumeThis mode of ascent could preserve ocean bulk content in jets, leading to jet sampling strategies being preferred for future missions [ABSTRACT FROM AUTHOR]

Published

2024

19. Triphenylphosphine‐Assisted Exsolution Engineering on Ruddlesden–Popper Perovskites for Promoting Oxygen Evolution.

Author

Bai, Juan, Shang, Jing, Mei, Jun, Qi, Dongchen, Liao, Ting, and Sun, Ziqi

Subjects

PEROVSKITE, IRIDIUM oxide, OXYGEN evolution reactions, OXYGEN, OXIDE ceramics, METALLIC surfaces

Abstract

Metal exsolution engineering has been regarded as a promising strategy for activating intrinsically inert perovskite oxide catalysts toward efficient oxygen evolution reaction. Traditional metal exsolution processes on perovskites are often achieved by using the reducing hydrogen gas; however, this is not effective for the relatively stable phase, such as Ruddlesden–Popper perovskite oxides. To address this issue, triphenylphosphine is proposed to be a reduction promotor for accelerating the reduction and migration of the target metal atoms, aiming to achieve the effective exsolution of metallic species from Ruddlesden–Popper‐type parent perovskites. Upon oxygen evolution reaction, these exsolved metallic aggregates are reconstructed into oxyhydroxides as the real active centers. After further modification by low‐percentage iridium oxide nanoclusters, the optimal catalyst delivered an overpotential as low as 305 mV for generating the density of 10 mA cm−2, outperforming these reported noble metal‐containing perovskite‐based alkaline oxygen evolution reaction electrocatalysts. This work provides a potential approach to activate catalytically inert oxides through promoting surface metal exsolution and explores a novel class of Ruddlesden–Popper‐type oxides for electrocatalytic applications. [ABSTRACT FROM AUTHOR]

Published

2024

20. Metal–Perovskite Interfacial Engineering to Boost Activity in Heterogeneous Catalysis.

Author

Malleier, Christoph and Penner, Simon

Subjects

CATALYTIC activity, HETEROJUNCTIONS, PEROVSKITE, HETEROGENEOUS catalysis, ENGINEERING

Abstract

In this review, we have assessed the possibility of metal–perovskite interfacial engineering to enhance the catalytic activity and selectivity in a range of heterogeneous catalytic reactions. We embarked on a literature screening of different perovskite material classes and reactions to show the versatility of the perovskite structures to induce the formation of such hetero-interfaces and the widespread nature of the phenomenon in catalytic research. There is almost no limitation on the chemical composition of the used perovskites and the nature of the catalyzed reaction, be it under reduction or oxidation conditions. We attempted to classify the perovskite materials, discuss the different strategies leading to the hetero-interfaces, and detail the synergistic action of the components of the respective interfaces. We also provide a critical assessment of the large body of data that is available in terms of a knowledge-based approach to the comparison of differently prepared interfaces with varying interfacial extent to gain a deeper understanding of the bi-functional operation of the interfaces and the urgent necessity to study and characterize such interfaces under realistic operation conditions. [ABSTRACT FROM AUTHOR]

Published

2024

21. Hydrogen Production from Methane with CO2 Utilization over Exsolution Derived Bimetallic NiCu/CeO2 Catalysts.

Author

Matus, E. V., Sukhova, O. B., Kerzhentsev, M. A., Ismagilov, I. Z., Yashnik, S. A., Ushakov, V. A., Larina, T. V., Gerasimov, E. Yu., Stonkus, O. A., Nikitin, A. P., Li, L., and Ismagilov, Z. R.

Abstract

Hydrogen production from methane with CO2 utilization over exsolution derived NiCu/CeO2 catalysts was studied. To form highly dispersed supported bimetallic NiCu particles the Ce0.75(NiCu)0.25O1.75 catalyst precursors (Cu/Ni molar ratio = 0; 0.004; 0.04; 0.25) were prepared by polymerizable complex method with the following reduction at 800 °C. A comparative study of the genesis, textural, structural and morphological properties of materials has been carried out by ex situ and in situ methods. It was shown that Ce0.75(NiCu)0.25O1.75 samples were fluorite-like ceria-based solid solutions with a mesoporous texture. Copper promotion has a positive effect on self-activation and hydrogen yield by improving the reducibility of the catalyst, lowering the exsolution temperature of the Ni2+ cations, and maintaining the concentration of oxygen vacancies. The catalyst of optimal composition NiCu/CeO2 (9.4 wt. % Ni, 0.4 wt. % Cu) formed from Ce0.75(NiCu)0.25O1.75 with Cu/Ni = 0.04 is resistant to coking and provides high hydrogen yield (82%) and CO2 utilization (78%) in steam/CO2 reforming of methane at 850 °C. [ABSTRACT FROM AUTHOR]

Published

2024

22. 湘西北黑色岩系中钛铀矿的结晶方式及对铀多金属成矿的指示意义.

Author

王健, 杨帆, 王文全, 王振云, and 李治兴

Abstract

Copyright of Uranium Geology is the property of Uranium Geology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

23. A/B 位计量比对脉冲电流促进钙钛矿 溶出行为的影响.

Author

付星, 齐锦刚, 孙立, 于文雯, 胡昕, 商剑, 唐立丹, and 赵作福

Abstract

Copyright of Chemical Engineering (China) / Huaxue Gongcheng is the property of Hualu Engineering Science & Technology Co Ltd. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

24. Methane Assisted Chemical Looping Water Splitting Performance of Sr2FeMo0.6Ni0.4O6-δ Double Perovskite for Solar Fuels Production

Author

Andrea Strazzolini, Francesco Orsini, Salvatore Francesco Cannone, Domenico Ferrero, Marta Boaro, Jordi Llorca, Georgios Dimitrakopoulos, Alessandro Trovarelli, Massimo Santarelli, and Ahmed Ghoniem

Subjects

Chemical Looping, Perovskite, Exsolution, Water Splitting, Solar Fuels, CH4 Reforming, Physics, QC1-999

Abstract

In this work, we performed a preliminary investigation on the redox behaviour of Sr2FeMo0.6Ni0.4O6-δ (SFMN) double perovskite in H2-H2O and CH4-H2O redox cycles in order to explore the potential use of this oxide as an Oxygen Carrier (OC) in fuel-assisted Chemical Looping Water Splitting (CLWS) processes driven by concentrated solar energy. The results were compared with our previous findings on the Reverse Water Gas Shift Chemical Looping (RWGS-CL) reaction. The improvement in performance due to the bimetallic exsolution on the OC surface is observed. This OC exhibits interesting activity and stability over CH4-assisted CLWS cycling. Future investigations are planned to examine the structural transformations that might impact the redox behaviour of this material in water splitting processes.

Published

2024

25. A brief review of single silicate crystal paleointensity: rock-magnetic characteristics, mineralogical backgrounds, methods and applications

Author

Chie Kato, Yoichi Usui, and Masahiko Sato

Subjects

Paleointensity, Single crystal, Magnetic inclusion, Exsolution, Geography. Anthropology. Recreation, Geodesy, QB275-343, Geology, QE1-996.5

Abstract

Abstract Single silicate crystals hosting tiny magnetic inclusions are remarkable targets to study the paleointensities of the Earth and extraterrestrial samples. Since the pioneering work done in late 1990s, paleointensity studies using various silicate minerals such as feldspar, quartz, zircon, pyroxene, and olivine with magnetic inclusions trapped during grain growth or exsolved from the host phase have been reported. It has been shown that some single crystals have the ability to record paleomagnetic information as reliable or more reliable than the whole rock, by direct comparison of the obtained paleointensity estimate from single crystal and the whole-rock sample or the magnetic observatory data. Various rock-magnetic studies also support the fidelity of these crystals. Here, we provide a brief review of the rock-magnetic characteristics of the single crystals, the mineralogical background of the hosting silicates, and experimental procedures developed to obtain reliable data from magnetically weak samples with distinctive rock-magnetic features. We also overview the studies on paleointensity and related topics on various terrestrial and extraterrestrial samples published mainly after the comprehensive reviews in late 2000s. The present review covers the advantages as well as the limitations and caveats of paleointensity studies using single crystal samples and will help readers who wish to utilize this technique in their research. Graphical Abstract

Published

2024

26. Evaluating oxide nanoparticle exsolution on A-site deficient PrBaCo2O6-δ electrodes

Author

Alfonso J Carrillo, María Balaguer, Cecilia Solís, Andrés López-García, Sylvio Haas, María Fabuel, Blanca Delgado-Galicia, Isabelle Rodriguez, Einar Vøllestad, Sebastian Wachowski, Ragnar Strandbakke, Truls Norby, and Jose M Serra

Subjects

exsolution, oxide nanoparticles, proton ceramic electrolyzers, A-site deficiency, double perovskites, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Renewable energy sources, TJ807-830

Abstract

Nanoparticle exsolution is a powerful technique for functionalizing redox oxides in energy applications, particularly at high temperatures. It shows promise for solid oxide fuel cells and electrolyzers. However, exsolution of other chemistries like metal oxides is not well studied, and the mechanism is poorly understood. This work explores oxide exsolution in PrBa _1− _x Co _2 O _6− _δ ( x = 0, 0.05, 0.1, 0.15) double perovskites, practiced electrodes in proton ceramic fuel cells and electrolyzers. Oxide exsolution in PrBa _1− _x Co _2 O _6− _δ aimed at boosting the electrocatalytic activity and was evaluated by varying intrinsic materials-related properties, viz. A-site deficiency and external parameters (temperature, under fixed time, and p O _2 = 10 ^−5 atm conditions). The materials were analyzed with conventional characterization tools and synchrotron-based small-angle x-ray scattering. Unlike metal-nanoparticle exsolution, increasing the A-site deficiency did not enhance the extent of oxide-nanoparticle exsolution, whereas larger nanoparticles were obtained by increasing the exsolution temperature. Combined Raman spectroscopy and electron microscopy analysis revealed that BaCoO _3 , Co _3 O _4 , and amorphous BaCO _3 nanoparticles were formed on the surface of the double perovskites after the reductive treatments. The present results demonstrate the complexity of oxide-nanoparticle exsolution in comparison with metal-nanoparticle exsolution. Further materials screening and mechanistic studies are needed to enhance our understanding of this method for functionalizing proton ceramic electrochemical cells (PCEC) electrodes.

Published

2025

27. Nanoparticle Exsolution on Perovskite Oxides: Insights into Mechanism, Characteristics and Novel Strategies

Author

Kim, Yo Han, Jeong, Hyeongwon, Won, Bo-Ram, Jeon, Hyejin, Park, Chan-ho, Park, Dayoung, Kim, Yeeun, Lee, Somi, and Myung, Jae-ha

Published

2024

28. A brief review of single silicate crystal paleointensity: rock-magnetic characteristics, mineralogical backgrounds, methods and applications.

Author

Kato, Chie, Usui, Yoichi, and Sato, Masahiko

Subjects

SINGLE crystals, OLIVINE, SILICATE minerals, MAGNETIC traps, PYROXENE, FELDSPAR, ZIRCON

Abstract

Single silicate crystals hosting tiny magnetic inclusions are remarkable targets to study the paleointensities of the Earth and extraterrestrial samples. Since the pioneering work done in late 1990s, paleointensity studies using various silicate minerals such as feldspar, quartz, zircon, pyroxene, and olivine with magnetic inclusions trapped during grain growth or exsolved from the host phase have been reported. It has been shown that some single crystals have the ability to record paleomagnetic information as reliable or more reliable than the whole rock, by direct comparison of the obtained paleointensity estimate from single crystal and the whole-rock sample or the magnetic observatory data. Various rock-magnetic studies also support the fidelity of these crystals. Here, we provide a brief review of the rock-magnetic characteristics of the single crystals, the mineralogical background of the hosting silicates, and experimental procedures developed to obtain reliable data from magnetically weak samples with distinctive rock-magnetic features. We also overview the studies on paleointensity and related topics on various terrestrial and extraterrestrial samples published mainly after the comprehensive reviews in late 2000s. The present review covers the advantages as well as the limitations and caveats of paleointensity studies using single crystal samples and will help readers who wish to utilize this technique in their research. [ABSTRACT FROM AUTHOR]

Published

2024

29. An Exsolved Cu Nanocatalyst for Highly Efficient Methanol Steam Reforming.

Author

Wei, Tong, Wang, B. S. Juan, Pan, Xueyan, and Harimoto, Tatsukuni

Subjects

STEAM reforming, COPPER, NANOPARTICLES, CATALYTIC activity, WATER vapor

Abstract

BaZr0.1Ce0.7Y0.2O3 (BZCY) perovskite with in‐situ exsolved metallic Cu catalyst acted as a catalyst for methanol steam reforming (MSR) for the first time. After reduction at 550 °C for 3 hours, fine and uniform metallic Cu nanoparticles were exsolved from the perovskite lattice with more active sites and oxygen vacancies on the surface. The reduced Ba0.9Zr0.1Ce0.7Y0.1Cu0.1O3 (BZCYCu) displayed a stable conversion of methanol above 99.9 % at 500 °C within 120 hours, with a negligible amount of CO in the outlet gas and no carbon species was detected on the surface of catalyst. The BZCYCu gained 7.4 % of their weight at 500 °C during the water vapor adsorption stage in temperature programmed water absorption experiment, which showed a considerable water adsorption capacity. Such a hygroscopicity could promote the catalytic methanol steam reforming and CO elimination. And metallic Cu has also been widely applied for the methanol steam reforming reaction due to their high activity and carbon resistance. The synergy of metallic Cu nanoparticles and perovskite substrate with more oxygen vacancies and well hydroscopicity improved the structural stability and ensured the catalytic activity of RBZCYCu catalysts. [ABSTRACT FROM AUTHOR]

Published

2024

30. Tailoring the A and B site of Fe-based perovskites for high selectivity in the reverse water-gas shift reaction

Author

Alex Martinez Martin, Shailza Saini, Dragos Neagu, Wenting Hu, Ian S. Metcalfe, and Kalliopi Kousi

Subjects

Reverse water-gas shift, CO2 utilization, Exsolution, Fe-Ni alloys, Lanthanide perovskites, Thermochemical CO2 reduction, Technology

Abstract

The reverse water-gas shift reaction (rWGS) is of particular interest as it is the first step to producing high-added-value products from carbon dioxide (CO2) and renewable hydrogen (H2), such as synthetic fuels or other chemical building blocks (e.g. methanol) through a modified Fischer-Tropsch process. However, side reactions and material deactivation issues, depending on the conditions used, still make it challenging. Efforts have been put into developing and improving scalable catalysts that can deliver high selectivity while at the same time being able to avoid deactivation through high temperature sintering and/or carbon deposition. Here we design a set of perovskite ferrites specifically tailored to the hydrogenation of CO2 via the reverse water-gas shift reaction. We tailor the oxygen vacancies, proven to play a major role in the process, by partially substituting the primary A-site element (Barium, Ba) with Praseodymium (Pr) and Samarium (Sm), and also dope the B-site with a small amount of Nickel (Ni). We also take advantage of the exsolution process and manage to produce highly selective Fe-Ni alloys that suppress the formation of any by-products, leading to up to 100% CO selectivity.

Published

2024

31. Perovskite-Type Oxides as Exsolution Catalysts in CO2 Utilization

Author

Thomas Ruh, Florian Schrenk, Tobias Berger, and Christoph Rameshan

Subjects

CO2 utilization, perovskite catalysts, exsolution, nanoparticles, closed carbon cycle, zero net emissions, Science

Abstract

Perovskite-type oxides (ABO3) are a highly versatile class of materials. They are compositionally flexible, as their constituents can be chosen from a wide range of elements across the periodic table with a vast number of possible combinations. This flexibility enables the tuning of the materials’ properties by doping the A- and/or B-sites of the base structure, facilitating the application-oriented design of materials. The ability to undergo exsolution under reductive conditions makes perovskite-type oxides particularly well-suited for catalytic applications. Exsolution is a process during which B-site elements migrate to the surface of the material where they form anchored and finely dispersed nanoparticles that are crucially important for obtaining a good catalytic performance, while the perovskite base provides a stable support. Recently, exsolution catalysts have been investigated as possible materials for CO2 utilization reactions like reverse water–gas shift reactions or methane dry reforming.

Published

2023

32. The development of fuel electrodes for high temperature solid oxide cells

Author

Zhang, Nuoxi and Irvine, John T. S.

Subjects

Fuel cell, CO2 electrolysis, Perovskite, Nanoparticles, Exsolution, Solid state chemistry, TK2931.Z5, Solid oxide fuel cells, Fuel cells, Electrolysis

Abstract

Our energetic matrix is currently based on finite fossil fuels, leading to climate change and increasing hazardous air pollutants. Nevertheless, solid oxide cells have emerged as a feasible and profitable route for energy generation. Solid oxide electrolysis cells can convert the excess electrical energy into chemical energy, thereby decoupling the transport fuels and chemicals production from today's fossil fuels, while solid oxide fuel cells can convert chemical energy back into electricity, thus balancing energy availability and demand. Solid oxide electrolysis cells afford an opportunity for upgrading biogas through the internal dry reforming of biogas and carbon dioxide electrolysis, producing hydrogen and carbon monoxide. Solid oxide electrolysis cells with conventional Ni-YSZ cermet fuel electrode and yttria stabilized zirconia electrolyte were constructed and tested on the direct feed of simulated biogas mixture (i.e. CH₄/CO₂ = 60/40, 50/50 and 40/60) at 850 °C. Cell performance and outlet gases measurements were carried out under open-circuit and closed-circuit conditions. The current densities at 1.8 V are -0.448, -0.678 and -0.876 A cm⁻² for the gas mixtures of CH₄/CO₂= 60/40, 50/50 and 40/60, respectively. The short term durability tests were performed in these three gas mixtures at 850 °C and 1.4 V. The cell fed with high CO₂ content demonstrates stable performance. No carbon deposition was observed on the Ni-YSZ fuel electrode surface, which might be due to not reaching the thermodynamic equilibrium and the reverse Boudouard reaction. Nonstoichiometric perovskites with active metal nanoparticles exsolved on the surface have been proposed as the promising fuel electrode in solid oxide cells. Here, La₀.₄₀Ca₀.₄₀TiO₃ and La₀.₄₃Ca₀.₃₇MχTi₁-χO₃-γ (M = Ni₀.₀₅, Ni₀.₁₀, Mn₀.₁₀, Co₀.₁₀, Ni₀.₀₅Mn₀.₀₅, and Ni₀.₀₅Co₀.₀₅) perovskite oxides were synthesized. The in-situ exsolution of Ni, Co and NiCo metal nanoparticles from the perovskite oxide parents was successfully according to the X-ray diffraction, scanning electron microscopy and high-resolution transmission electron microscopy. The results demonstrate that the exsolved metal nanoparticles can enhance the electrical conductivity, catalytic activity toward the hydrogen oxidation end carbon dioxide reduction. The cell performance can be improved by employing high voltage electrochemical reduction and extending the electrochemical reduction time. The best cell performance in 3% H₂O/H₂ was achieved by La₀.₄₃Ca₀.₃₇Ni₀.₁₀Ti₀.₉₀O₃-γ, exhibiting the maximum power density of 1.50 W cm⁻² at 900 °C. La₀.₄₃Ca₀.₃₇Co₀.₁₀Ti₀.₉O₃-γ based solid oxide electrolysis cell displays the highest current density of 0.856 A cm⁻² at 1.4 V.

Published

2022

33. The development of SOFC with perovskite electrodes by co-sintering and co-casting method

Author

Nowicki, Kamil and Irvine, John T. S.

Subjects

SOFC, Exsolution, Tubular SOFC, Perovskite electrodes, Tape casting, Cosintering

Abstract

The Solid Oxide Fuel Cells (SOFCs) were produced with various geometries by tape casting and co-sintering. Tape casting is a cheap and easily scalable method employed on a large scale for thin layers preparation. In the project, a sequential casting technique was developed where all the function layers in SOFC assembly were cast on each other; co-casting gave a strong interface and reduced electrolyte thickness. Co-sintering further simplified cells manufacturing and reduced processing time and energy demand, making fuel cells more profitable and suitable for mass production. The crucial factor for co-sintering of various-material tapes is to ensure that they have close shrinkage profiles during the sintering step, which usually differ due to individual properties of ceramic materials and pore former's concentration in the slurry. The minor differences create stress between layers, leading to delamination and cracks in the cell's structure. By controlling the composition of the slurry, particle size distribution and sintering temperature, it was possible to produce a cell without any internal structural defects. The developed method was used to produce SOFC with alternative SOFCRoll geometry and the small tubular cells. SOFCRoll gives the possibility to extend the surface area while keeping the volume low. Up to 27.75 cm² of surface area was incorporated in a spiral structure, with a volume of about 2.5 cm³, thus giving better applicability where size reduction is required and a more robust structure; however, the cell was suffered a performance loss due to complications with the current collection and gas distribution. The structure modification and co-sintering of the current collector with high Ni content into otherwise unavailable part of the cell allowed for optimal use of 12 cm² surface area in the smaller version of the cell. Tubular cells are known for their high mechanical and thermal resistance. Tubular cell's surface area was up to 7 cm², much lower than in SOFCRoll but more accessible for gas and current collector. The combination of a small tubular design with thermally and redox stable alternative perovskite fuel electrode gave a highly durable device; without noticeable degradation after testing in extreme conditions. Through the project, composite electrodes were mainly used, co-cast, and co-sintered with electrolyte at 1350 °C. The state-of-art yttria-stabilised zirconia (Zr₀.₈₄Y₀.₁₆O₁.₉₂, YSZ) was used as the electrolyte, which offers good performance and commercial availability. The co-sintered active fuel electrode contained the nickel-doped lanthanum calcium titanate (La₀.₄₃Ca₀.₃₇Ni₀.₀₆Ti₀.₉₄O[sub](3-γ), LCNT) and YSZ. The co-sintered oxygen electrode was a composite of lanthanum strontium manganate ((La₀.₈Sr₀.₂)₀.₉₅MnO₃, LSM) and YSZ. LCNT belongs to the family of new alternative materials proposed to replace highly active but prone to degradation state-of-the-art Ni/YSZ composite. Thanks to its mixed ionic and electronic properties (MIEC) and the possibility of exsolving nickel nanoparticles on its surface, LCNT offers a high activity for hydrogen oxidation whilst possessing great thermal shock and redox resistance as a fully ceramic electrode. Despite the successful co-sintering of the LCNT/YSZ fuel electrode and LSM/YSZ oxygen electrode into a SOFCRoll and tubular structure, due to limitations related to the sintering temperature and composition, electrodes showed a significant ohmic and polarisation resistance. In the following experiment, the composite electrodes were replaced. For the development of the next generation of tubular cells, the active material was impregnated into a co-sintered porous YSZ backbone. For impregnated electrodes, LCNT was impregnated on a porous YSZ backbone for the fuel hydrogen side, while on the air electrode, a lanthanum strontium ferrite (La₀.₈Sr₀.₂FeO₃, LSF). The impregnated electrodes were sintered at a much lower temperature than in state-of-the-art methods, giving more active spatial microstructures with a large surface area. Using this technique in co-sintered cells simplified manufacturing and made a broader range of materials available. This work contains complete procedures for producing SOFC with various designs, including planar, tubular, and SOFCRoll, by the outlined methods. In addition, it seeks to determine a mechanism of their functionality based on electrochemical tests and DRT analysis.

Published

2022

34. Preparation of heterostructured Cu-CeO2/SrTiO3 catalysts by rapid plasma exsolution for photothermal reverse water gas shift reaction

Author

Zihe Zhu, Jun Zhou, Qinghao Li, Zhengrong Liu, Qinyuan Deng, Zilin Zhou, Cunxin Li, Lei Fu, Jiacheng Zhou, Haonan Li, Qiankai Zhang, and Kai Wu

Subjects

Photothermal, RWGS, Exsolution, Plasma, Technology

Abstract

High catalytic performances of metal-semiconductor heterostructures have gained significant attention in recent years. However, developing fast and low-cost synthesis of multiphase heterojunction catalysts has long been a challenge. Herein, three phases of Cu-CeO2-SrTiO3-δ heterojunction catalyst are successfully synthesized by combining with sol-gel and rapid plasma exsolution method. Using dielectric barrier discharge plasma (DBD), Cu nanoparticles are exsolved and uniformly distributed on the surface of CeO2-SrTiO3-δ. This unique multiphase heterojunction catalyst exhibits superior performance in photothermal reverse water gas shift (RWGS) reactions. The yield of CO from this catalyst is impressive at 11.32 mmol g−1 h−1, 9 times greater than pure SrTiO3, and the selectivity for CO is high (99.95%). The enhanced activity is primarily attributed to the synergistic effect resulting from the incorporation of three phases of Cu nanoparticles, CeO2, and SrTiO3-δ, as well as their interfaces. The increase in oxygen vacancy sites in CeO2 enhances the adsorption of CO2, whereas the doping and exsolution of Cu help to broaden the light absorption range. A significant role is played by the localized surface plasmon resonance (LSPR) effect of Cu nanoparticles in promoting the catalytic performance of RWGS. This study demonstrates a simple and efficient method for fabricating multiphase heterojunction catalysts, providing new strategies for photothermal CO2 reduction.

Published

2024

35. Mechanisms of helium differential enrichment and helium‐nitrogen coupling: A case study from the Weiyuan and Anyue gas fields, Sichuan Basin, China.

Author

Zhao, Dong, Wang, Xiaofeng, Liu, Wenhui, Li, Xiaobin, Zhang, Dongdong, Li, Xiaofu, and Zhang, Jiayu

Subjects

*GAS reservoirs, *GAS fields, *HELIUM, *NITROGEN in soils, *PARTIAL pressure, *PORE water, *NATURAL gas

Abstract

The helium (He) contents of the Weiyuan and Anyue gas fields in the Sichuan Basin (China) differ significantly despite their similar helium‐nitrogen (N2) coupling characteristics, that is, the positive correlation between the N2 and He contents, and the negative correlation between the nitrogen/helium (N2/He) ratio and depth. To determine the factors influencing the differential enrichment of He resources and He–N2 coupling in the Weiyuan and Anyue gas fields, this study analysed the compositions of natural gases within the study area and established a computational model for evaluating the dissolution and exsolution amount of He and N2 in the pore water. The results indicated that: the uplift of the basement granite was crucial for the exsolution and enrichment of dissolved helium, and it was also the main reason for He–N2 coupling. The differential uplift that occurred in the Leshan–Longnvsi palaeo‐uplift during the Himalayan period further promoted the differential enrichment of He resources, thus also impacting the N2/He ratio in the study area. The distinct quantities of N2 and He exsolution during the uplift directly affected the negative correlation between the N2/He ratio and the depth. Within the same depth range of the uplift, the average and variations of the N2/He ratio in the crust‐derived helium‐rich natural gas reservoir were inversely proportional to the in situ molar partial pressure of He. The uplift of the crystalline basement is an important mechanism that causes the enrichment of helium resources and the coupling of helium‐nitrogen in the crust‐derived helium‐rich natural gas reservoir, which is of great significance for understanding the variation of N2/He ratio and exploration of He resources. [ABSTRACT FROM AUTHOR]

Published

2024

36. Effect of solid solution treatment on microstructure and properties of extruded 7055 aluminum alloy.

Author

Zhao, Hui, Cheng, Quan-shi, Zhao, Yan, Kang, Yuan, Zhang, Wen-jing, and Ye, Ling-ying

Abstract

Copyright of Journal of Central South University is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

37. Exsolution versus particle segregation on (Ni,Co)-doped and undoped SrTi0.3Fe0.7O3-δ perovskites: Differences and influence of the reduction path on the final system nanostructure.

Author

Santaya, Mariano, Jiménez, Catalina Elena, Arce, Mauricio Damián, Carbonio, Emilia Andrea, Toscani, Lucia Maria, Garcia-Diez, Raul, Knop-Gericke, Axel, Mogni, Liliana Verónica, Bär, Marcus, and Troiani, Horacio Esteban

Subjects

*SOLID oxide fuel cell electrodes, *PEROVSKITE, *SOLID oxide fuel cells, *SURFACE segregation

Abstract

Exsolution is one of the most successful functionalization techniques to improve the catalytic activity of electrodes in solid oxide fuel and electrolyzer cells (SOFC/SOEC). The objective of this technique is to produce the highest possible number of metallic nanoparticles on the surface of a host-oxide, without significantly altering its structure. In this work, we compare three similar SOFC electrodes: STF (SrTi 0.3 Fe 0.7 O 3), STFN (Sr 0.93 Ti 0.3 Fe 0.63 Ni 0.07 O 3), and STFNC (Sr 0.93 Ti 0.3 Fe 0.56 Ni 0.07 Co 0.07 O 3), revealing that there is a significant difference between Ni–Fe/Ni–Co–Fe nanoparticle formation in STFN/STFNC and pure Fe0 particle formation in STF, which is evidenced by the size and amount of produced nanoparticles, but also by their anchoring to the host-oxide. The terms exsolution and particle segregation will be used, respectively, to distinguish these phenomena. Next, we explore two different reduction methods and observe that the characteristics of exsolution do not only depend on temperature, atmosphere and reduction times, but also on the reduction path taken to reach such conditions. [Display omitted] • Exsolution differs from particle segregation in the NP distribution, density, size and anchorage. • The characteristics of exsolved NPs are influenced by the hydrogen reduction path. • In-situ absorption spectroscopy is used to determine the exsolution temperature threshold. [ABSTRACT FROM AUTHOR]

Published

2023

38. Perovskite-Type Oxides as Exsolution Catalysts in CO 2 Utilization.

Author

Ruh, Thomas, Schrenk, Florian, Berger, Tobias, and Rameshan, Christoph

Subjects

CARBON dioxide, CATALYSTS, CERAMICS, OXIDES, PERIODIC table of the elements, SURFACES (Technology), OXIDE ceramics

Abstract

Definition: Perovskite-type oxides (ABO3) are a highly versatile class of materials. They are compositionally flexible, as their constituents can be chosen from a wide range of elements across the periodic table with a vast number of possible combinations. This flexibility enables the tuning of the materials' properties by doping the A- and/or B-sites of the base structure, facilitating the application-oriented design of materials. The ability to undergo exsolution under reductive conditions makes perovskite-type oxides particularly well-suited for catalytic applications. Exsolution is a process during which B-site elements migrate to the surface of the material where they form anchored and finely dispersed nanoparticles that are crucially important for obtaining a good catalytic performance, while the perovskite base provides a stable support. Recently, exsolution catalysts have been investigated as possible materials for CO2 utilization reactions like reverse water–gas shift reactions or methane dry reforming. [ABSTRACT FROM AUTHOR]

Published

2023

39. Systematic in situ Investigation of the Formation of NH3 Cracking Catalysts from Precursor Perovskites ABO3 (A=La,Ca,Sr and B=Fe,Co,Ni) and their Catalytic Performance.

Author

Gallus, Simone and Weidenthaler, Claudia

Subjects

*PEROVSKITE, *CATALYSTS, *TRANSITION metals, *X-ray diffraction, *ELECTRONEGATIVITY, *STRONTIUM

Abstract

This work addresses the formation of ammonia (NH3) decomposition catalysts derived from perovskites ABO3 (A=La, Ca, Sr, and B=Fe, Co, Ni) precursors via operando synchrotron X‐ray diffraction experiments. During the reaction in NH3, the perovskite precursors are decomposed and the transition metals are reduced. Depending on their reduction properties, active metallic catalysts are formed in situ on La2O3 as support. The reduction behavior of the perovskites, formation of intermediate phases during activation, and catalytic performance was studied in detail. In addition, microstructure properties such as crystallite sizes and particle morphology were analyzed. Co‐/Ni‐based perovskites decomposed completely during activation to Co0/Ni0 supported on La2O3 while Fe‐based perovskites were fully stable but inactive in catalysis. This difference is due to varying electronic properties of the transition metals, e. g. decreasing electronegativity from Ni to Fe. With decreasing reducibility, the intermediate phases during activation formed more distinct. La3+ was partially substituted by Ca2+/Sr2+ in LaCoO3 to test for advantageous effects in NH3 decomposition. The best performance was observed using the precatalyst La0.8Sr0.2CoO3 with a conversion of 86 % (100 % NH3, 15000 mL g−1 h−1) at 550 °C. [ABSTRACT FROM AUTHOR]

Published

2023

40. Advances in Materials and Interface Understanding in Protonic Ceramic Fuel Cells.

Author

Tsvetkov, Nikolai, Kim, Dongyeon, Jeong, Incheol, Kim, Jun Hyuk, Ahn, Sejong, Lee, Kang Taek, and Jung, WooChul

Subjects

*ENERGY conversion, *CERAMIC materials, *SOLID oxide fuel cells, *CHARGE exchange, *ELECTRODES

Abstract

Protonic ceramic fuel cells (PCFCs) are promising eco‐energy electrochemical energy conversion systems that can efficiently operate in intermediate (500–700 °C) to low (500 °C) temperature ranges. In this review the most recent advances in materials research for the ceramic components of PCFCs (i.e., electrolyte, cathode, and anode) and their interface engineering are introduced. Recent approaches to improve the protonic of conductivity, and activity and stability of electrolyte and electrode materials are first presented. In addition, new attempts to stabilize/activate electrode/electrolyte interfaces and electrode surfaces are also discussed. Details of the theoretical background behind the electron and ion transfer processes at electrodes are also discussed. Finally, the challenges and perspectives of PCFC development are suggested from the point of view of materials engineering. [ABSTRACT FROM AUTHOR]

Published

2023

41. A Mini-Review on Lanthanum–Nickel-Based Perovskite-Derived Catalysts for Hydrogen Production via the Dry Reforming of Methane (DRM).

Author

Georgiadis, Amvrosios G., Charisiou, Nikolaos D., and Goula, Maria A.

Subjects

*HYDROGEN production, *CATALYSTS, *HYDROGEN economy, *TECHNOLOGICAL innovations, *METHANE, *STEAM reforming

Abstract

Given that the attempts to head toward a hydrogen economy are gathering pace, the dry reforming of methane (DRM) to produce hydrogen-rich syngas is a reaction that is worthy of investigation. Nickel-based catalysts have been extensively examined as a cost-effective solution for DRM, though they suffer from fast deactivation caused by coke accumulation. However, a number of published studies report high catalytic performance in terms of both activity and stability for La–Ni-based perovskite-derived catalysts used in DRM in comparison to other corresponding materials. In the work presented herein, a thorough analysis regarding the application of La–Ni-based perovskite catalysts for DRM is carried out. LaNiO3 is known for its anti-coking ability owing to the strong interaction between CO2 and La2O3. A further modification to improve the catalytic performance can be achieved by the partial or complete substitution of A or/and B sites of the perovskite catalysts. The latest developments with respect to this topic are also discussed in this manuscript. Even though the low surface area of perovskite catalysts has always been an obstacle for their commercialization, new supported and porous perovskite materials have recently emerged to address, at least partly, the challenge. Finally, conclusions and future outlooks for developing novel perovskite catalysts that may potentially pioneer new technology are included. [ABSTRACT FROM AUTHOR]

Published

2023

42. Apatite in brachinites: Insights into thermal history and halogen evolution.

Author

Zhang, Lang, Zhang, Ai-Cheng, and Wang, Shu-Zhou

Subjects

*APATITE, *SILICATE minerals, *HALOGENS, *CRYSTAL grain boundaries, *FLUORAPATITE, *CHROMITE

Abstract

Apatite is an important petrogenetic indicator in extraterrestrial materials. Here, we report the mineralogical features of apatite and associated phases in three brachinites Northwest Africa (NWA) 4969, NWA 10637, and NWA 11756. Two types of apatite are observed: intergranular apatite and apatite inclusion within chromite and silicate minerals. The intergranular chlorapatite is enclosed by or penetrated by irregular porous merrillite, indicating chlorapatite replacement by merrillite. The intergranular chlorapatite is closely associated with a fine-grained pyroxene-troilite intergrowth along olivine grain boundaries, which is a sulfidization product of olivine. High-Ca pyroxene is observed as a constituent phase in the intergrowth for the first time. The apatite inclusions are either monomineralic or closely associated with subhedral-euhedral pore-free merrillite. In NWA 4969, the apatite inclusions show a large compositional variation from chlorapatite to fluorapatite and are systematically more F-rich than intergranular apatite; while the apatite inclusions in NWA 10637 and NWA 11756 are chlorapatite. Most of the two apatite types in brachinites contain oriented tiny or acicular chromite grains, suggesting the exsolution of chromite from apatite. We propose that apatite replacement by merrillite, formation of pyroxene-troilite intergrowth, and exsolution of chromite in apatite were caused by a shock-induced, transient heating event (~930–1000 °C) on the brachinite parent body. This heating event resulted in halogen devolatilization during replacement of the intergranular apatite by merrillite, which probably disturbed the Mn-Cr isotopic system in brachinites as well. We also propose that the apatite inclusions could be a residual precursor material of the brachinites. [ABSTRACT FROM AUTHOR]

Published

2023

43. Renewable syngas & hydrogen synthesis via steam reforming of glycerol over ceria-mediated exsolved metal nano catalysts.

Author

Umar, Ahmed, Neagu, Dragos, and Irvine, John T.S.

Subjects

*METAL catalysts, *STEAM reforming, *HYDROGEN production, *SURFACE chemistry, *SYNTHESIS gas, *NICKEL catalysts, *GLYCERIN

Abstract

Currently, catalyst design and development has drawn much attention as results of its strategic importance in the area of energy applications particular those involving biomass conversion. This work tailored exsolution of metal catalysts through the use of ceria for enhanced structural and catalytic behaviour in steam reforming of glycerol. Aside the understanding that defects due to A-site deficiency facilitates formation of vacant sites and exsolution of metal catalysts on the B-site of perovskite systems, this work has exemplified that metals such as ceria significantly influences the exsolution and general morphological surface architecture and catalytic behaviour. The exsolved nickel catalysts anchored and socketed on a titanate support and the ceria's basic surface properties and oxygen storage-release behaviour has modified the perovskite surface chemistry and enhanced catalytic behaviour particularly deactivation due to carbon deposition and reusability. Other exsolvable dopant metal species such as Fe and Co forms alloys with nickel on the surface and the synergy between the dopant metals in the alloy yielded better results. Furthermore, in one of the catalyst systems, the most commonly observed tolerable A-site deficiency and doping limit of 2% known for SrTiO 3 perovskite was overstretched by 0.5% (2.5%) thereby increasing the defect chemistry. The catalyst system with such formulation has shown a dramatic exsolution phenomenon and catalytic behaviour and robust suppression of coke deposition. CO selectivity >60% and H 2 selectivity >40% was recorded with all the catalyst systems. The catalysts used in this work are useful for applications in energy and production of value added chemicals. • Ceria enhances and mediates exsolution of nano metal catalysts. • Exsolved nono metals forms alloys with improved structural and surface chemistry. • High stability, reusability and great suppression of carbon deposition. • Overstretching of doping ratio by 0.5% enhanced defect chemistry and exsolution. [ABSTRACT FROM AUTHOR]

Published

2023

44. Phase Transition Engineering of Host Perovskite toward Optimal Exsolution‐facilitated Catalysts for Carbon Dioxide Electrolysis.

Author

Zhang, Bo‐Wen, Zhu, Meng‐Nan, Gao, Min‐Rui, Chen, Jian, Xi, Xiuan, Shen, Jing, Feng, Ren‐Fei, Semagina, Natalia, Duan, Nanqi, Zeng, Hongbo, and Luo, Jing‐Li

Subjects

*PHASE transitions, *CARBON dioxide, *PEROVSKITE, *CATALYSTS, *CATALYTIC activity, *SOLID oxide fuel cells

Abstract

The in situ exsolution technique of nanoparticles has brought new opportunities for the utilization of perovskite‐based catalysts in solid oxide cells. However, the lack of control over the structural evolution of host perovskites during the promotion of exsolution has restricted the architectural exploitation of exsolution‐facilitated perovskites. In this study, we strategically broke the long‐standing trade‐off phenomenon between promoted exsolution and suppressed phase transition via B‐site supplement, thus broadening the scope of exsolution‐facilitated perovskite materials. Using carbon dioxide electrolysis as an illustrative case study, we demonstrate that the catalytic activity and stability of perovskites with exsolved nanoparticles (P‐eNs) can be selectively enhanced by regulating the explicit phase of host perovskites, accentuating the critical role of the architectures of perovskite scaffold in catalytic reactions occurring on P‐eNs. The concept demonstrated could potentially pave the way for designing the advanced exsolution‐facilitated P‐eNs materials and unveiling a wide range of catalytic chemistry taking place on P‐eNs. [ABSTRACT FROM AUTHOR]

Published

2023

45. The Exsolution of Cu Particles from Doped Barium Cerate Zirconate via Barium Cuprate Intermediate Phases.

Author

Wang, Mei, Papaioannou, Evangelos I., Metcalfe, Ian S., Naden, Aaron, Savaniu, Cristian D., and Irvine, John T. S.

Subjects

*COPPER, *BARIUM zirconate, *ETHANOL, *SOLID state proton conductors, *METAL nanoparticles, *PRECIOUS metals, *CUPRATES, *PROTON transfer reactions

Abstract

As a low‐cost alternative to noble metals, Cu plays an important role in industrial catalysis, such as water‐gas shift reaction, methanol or ethanol oxidation, hydrogenation of oils, CO oxidation, among many others. An important step in optimizing Cu catalyst performance is control of nanoparticles size, distribution, and the interface with the support. While proton conducting perovskites can enhance the metal catalytic activity when acting as the support, there has been limited investigation of in situ growth of Cu metal nanoparticles from the proton conductors and its catalytic performance. Here, Cu nanoparticles are tracked exsolved from an A‐site‐deficient proton‐conducting barium cerate‐zirconate using scanning electron microscopy, revealing a continuous phase change during exsolution as a function of reduction temperature. Combined with the phase diagram and cell parameter change during reduction, a new exsolution mechanism is proposed for the first time which provides insight into tailoring metal particles interfaces at proton conducting oxide surfaces. Furthermore, the catalytic behavior in the CO oxidation reaction is explored and, it is observed that these new nanostructures can rival state of the art catalysts over long term operation. [ABSTRACT FROM AUTHOR]

Published

2023

46. NiCu Alloy/Perovskite Nanoparticle Catalyst for Methanol Steam Reforming via Prereduction and In Situ Exsolution Technology.

Author

Wei, Tong, Pan, Xueyan, Jia, Yangbo, Wang, Juan, Zheng, Chengming, and Qiu, Peng

Abstract

A La0.9Ce0.1Mn0.8Ni0.1Cu0.1O3 (LCMNCu) perovskite nanomaterial with in situ-exsolved metallic nanoparticles (Re-LCMNCu) was fabricated successfully and acted as a catalyst for methanol steam reforming. Due to the fine and uniform NiCu alloy nanoparticles (∼35 nm) exsolved from the ceramic substrate, Re-LCMNCu displayed a stable conversion of methanol above 99% at 350 °C and maintained a hydrogen production rate of 285 mmol h–1 gcat–1 for 60 h, with a negligible amount of CO in the outlet gas. The NiCu alloy played an important role in catalytic activity, and the optimal prereduction treatment condition for catalyst activation was determined to be 6 h. Upon further examination, the NiCu alloy partially embedded into the substrate ensured high catalytic performance and the synergy between the NiCu alloy, CeO2 promoter, and perovskite substrate with more oxygen vacancies improved the catalytic activity of Re-LCMNCu catalysts. [ABSTRACT FROM AUTHOR]

Published

2023

47. Suppression of Oxygen Vacancies in Rutile Ruo2 via In Situ Exsolution for Enhanced Water Electrocatalysis.

Author

Zhang, Yudi, Wang, Yan, Sun, Wen, Ma, Dandan, Ma, Jinfu, Rao, Jiancun, Xu, Qiunan, Huo, Juntao, Liu, Jian, and Li, Guowei

Subjects

ELECTROCATALYSIS, OXYGEN evolution reactions, CATALYST structure, OXYGEN, PEROVSKITE, THRESHOLD energy, ELECTRONIC structure, RUTILE

Abstract

Elemental vacancies are proposed as an effective approach to tuning the electronic structure of catalysts that are critical for energy conversion. However, for reactions such as the sluggish oxygen evolution reaction, the excess of oxygen vacancies (VO) is inevitable and detrimental to catalysts' electrochemical stability and activities, e.g., in the most active RuO2. While significant work is carried out to hinder the formation of VO, the development of a fast and efficient strategy is limited. Herein, a protection SrO layer produced successfully at the surface of RuO2 with the in situ exsolution method with perovskite SrRuO3 as the precatalyst, which could significantly hinder the generation of VO. Benefited from the suppression of VO, the surface‐modified RuO2 requires a low overpotential of 290 mV at 100 mA cm−2, accompanied by remarkably high electrochemical stability (100 h) and Faraday efficiency (≈100%). Theoretical investigation reveals that the formation energy of VO in RuO2 is almost doubled in the exsolved RuO2 phase as a result of the weakened RuO bond covalency. This work not only provides insight into the structural evolution of perovskite oxide catalysts but also demonstrates the feasibility of controlling vacancy formation via in situ exsolution. [ABSTRACT FROM AUTHOR]

Published

2023

48. Nd 2−x Sr x NiO 4 Solid Solutions: Synthesis, Structure and Enhanced Catalytic Properties of Their Reduction Products in the Dry Reforming of Methane.

Author

Shlyakhtin, Oleg A., Timofeev, Grigoriy M., Malyshev, Sergey A., Loktev, Alexey S., Mazo, Galina N., Shatalova, Tatiana, Arkhipova, Veronika, Roslyakov, Ilya V., and Dedov, Alexey G.

Subjects

*SOLID solutions, *CATALYTIC reduction, *GAS mixtures, *CATALYTIC activity, *STEAM reforming, *THERMAL analysis, *METHANE as fuel, *METHANE

Abstract

Solid solutions Nd2−xSrxNiO4±δ (x = 0, 0.5, 1, 1.2, 1.4) with a K2NiF4 structure can be obtained from freeze-dried precursors. The end members of this series can be obtained at T ≥ 1000 °C only, while complex oxides with x = 1; 1.5 are formed at T ≥ 700 °C. Thermal analysis revealed the two stages of Nd2−xSrxNiO4±δ thermal reduction in a 10%H2/Ar gas mixture that was completed at 900 °C. For x < 0.2, the reduction products demonstrated an exsolution-like morphology with Ni nanoparticles allocated at the surface of oxide grains. As-obtained nanocomposites with x = 0 and x > 1 revealed the outstanding catalytic activity and selectivity in the dry reforming of the methane (DRM) reaction at 800 °C with CH4 conversion close to the thermodynamic values. The appearance of two different maxima of the catalytic properties of Ni/(Nd2O3,SrCO3) nanocomposites could be affiliated with the domination of the positive contributions of Nd2O3 and SrCO3, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

49. Insights into the Contribution of Oxidation-Reduction Pretreatment for Mn 0.2 Zr 0.8 O 2−δ Catalyst of CO Oxidation Reaction.

Author

Mishchenko, Denis D., Vinokurov, Zakhar S., Afonasenko, Tatyana N., Saraev, Andrey A., Simonov, Mikhail N., Gerasimov, Evgeny Yu., and Bulavchenko, Olga A.

Subjects

*CATALYSIS, *X-ray diffraction, *CATALYTIC oxidation, *TRANSMISSION electron microscopy, *CATALYSTS, *WATER gas shift reactions, *OXIDATION

Abstract

A Mn0.2Zr0.8O2−δ mixed oxide catalyst was synthesized via the co-precipitation method and studied in a CO oxidation reaction after different redox pretreatments. The surface and structural properties of the catalyst were studied before and after the pretreatment using XRD, XANES, XPS, and TEM techniques. Operando XRD was used to monitor the changes in the crystal structure under pretreatment and reaction conditions. The catalytic properties were found to depend on the activation procedure: reducing the CO atmosphere at 400–600 °C and the reaction mixture (O2 excess) or oxidative O2 atmosphere at 250–400 °C. A maximum catalytic effect characterized by decreasing T50 from 193 to 171 °C was observed after a reduction at 400 °C and further oxidation in the CO/O2 reaction mixture was observed at 250 °C. Operando XRD showed a reversible reduction-oxidation of Mn cations in the volume of Mn0.2Zr0.8O2−δ solid solution. XPS and TEM detected the segregation of manganese cations on the surface of the mixed oxide. TEM showed that Mn-rich regions have a structure of MnO2. The pretreatment caused the partial decomposition of the Mn0.2Zr0.8O2−δ solid solution and the formation of surface Mn-rich areas that are active in catalytic CO oxidation. In this work it was shown that the introduction of oxidation-reduction pretreatment cycles leads to an increase in catalytic activity due to changes in the origin of active states. [ABSTRACT FROM AUTHOR]

Published

2023

50. Exsolved materials for CO2 reduction in high-temperature electrolysis cells.

Author

Min Xu, Ran Cao, Han Qin, Nuoxi Zhang, Wenle Yan, Liming Liu, Irvine, John T. S., and Di Chen

Subjects

CARBON dioxide reduction, ELECTROLYSIS, HIGH temperatures, HETEROGENEOUS catalysts, ELECTROCHEMICAL analysis

Abstract

Electrochemical reduction of CO2 into valuable fuels and chemicals has become a contemporary research area, where the heterogeneous catalyst plays a critical role. Metal nanoparticles supported on oxides performing as active sites of electrochemical reactions have been the focus of intensive investigation. Here, we review the CO2 reduction with active materials prepared by exsolution. The fundamental of exsolution was summarized in terms of mechanism and models, materials, and driven forces. The advances in the exsolved materials used in hightemperature CO2 electrolysis were catalogued into tailored interfaces, synergistic effects on alloy particles, phase transition, reversibility and electrochemical switching. [ABSTRACT FROM AUTHOR]

Published

2023