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1. Thermal stability and coalescence dynamics of exsolved metal nanoparticles at charged perovskite surfaces

Author

Moritz L. Weber, Dylan Jennings, Sarah Fearn, Andrea Cavallaro, Michal Prochazka, Alexander Gutsche, Lisa Heymann, Jia Guo, Liam Yasin, Samuel J. Cooper, Joachim Mayer, Wolfgang Rheinheimer, Regina Dittmann, Rainer Waser, Olivier Guillon, Christian Lenser, Stephen J. Skinner, Ainara Aguadero, Slavomír Nemšák, and Felix Gunkel

Subjects
Science
Abstract

Abstract Exsolution reactions enable the synthesis of oxide-supported metal nanoparticles, which are desirable as catalysts in green energy conversion technologies. It is crucial to precisely tailor the nanoparticle characteristics to optimize the catalysts’ functionality, and to maintain the catalytic performance under operation conditions. We use chemical (co)-doping to modify the defect chemistry of exsolution-active perovskite oxides and examine its influence on the mass transfer kinetics of Ni dopants towards the oxide surface and on the subsequent coalescence behavior of the exsolved nanoparticles during a continuous thermal reduction treatment. Nanoparticles that exsolve at the surface of the acceptor-type fast-oxygen-ion-conductor SrTi0.95Ni0.05O3−δ (STNi) show a high surface mobility leading to a very low thermal stability compared to nanoparticles that exsolve at the surface of donor-type SrTi0.9Nb0.05Ni0.05O3−δ (STNNi). Our analysis indicates that the low thermal stability of exsolved nanoparticles at the acceptor-doped perovskite surface is linked to a high oxygen vacancy concentration at the nanoparticle-oxide interface. For catalysts that require fast oxygen exchange kinetics, exsolution synthesis routes in dry hydrogen conditions may hence lead to accelerated degradation, while humid reaction conditions may mitigate this failure mechanism.

Published
2024
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2. Impact of Transition Metal Layer Vacancy on the Structure and Performance of P2 Type Layered Sodium Cathode Material

Author

Orynbay Zhanadilov, Sourav Baiju, Natalia Voronina, Jun Ho Yu, A-Yeon Kim, Hun-Gi Jung, Kyuwook Ihm, Olivier Guillon, Payam Kaghazchi, and Seung-Taek Myung

Subjects
Layered oxide, Oxygen evolution, Sodium battery, Vacancy, Cathode, Technology
Abstract

Highlights Vacancy in the transition metal layer of sodium cathode material induces the formation lone-pair electrons in the O 2p orbital. Material delivers more capacity from the oxygen redox validated by density functional calculation. Widened dominance of the OP4 phase without releasing O2 gas.

Published
2024
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3. Direct Precursor Route for the Fabrication of LLZO Composite Cathodes for Solid‐State Batteries

Author

Vivien Kiyek, Christian Schwab, Walter Sebastian Scheld, Christoph Roitzheim, Adrian Lindner, Wolfgang Menesklou, Martin Finsterbusch, Dina Fattakhova‐Rohlfing, and Olivier Guillon

Subjects
all‐solid–state batteries, ceramic composites, in situ synthesis, LLZO, Science
Abstract

Abstract Solid–state batteries based on Li7La3Zr2O12 (LLZO) garnet electrolyte are a robust and safe alternative to conventional lithium‐ion batteries. However, the large‐scale implementation of ceramic composite cathodes is still challenging due to a complex multistep manufacturing process. A new one‐step route for the direct synthesis of LLZO during the manufacturing of LLZO/LiCoO2 (LCO) composite cathodes based on cheap precursors and utilizing the industrially established tape casting process is presented. It is shown that Al, Ta:LLZO can be formed directly in the presence of LCO from metal oxide precursors (LiOH, La2O3, ZrO2, Al2O3, and Ta2O5) by heating to 1050 °C, eliminating the time‐ and energy‐consuming synthesis of preformed LLZO powders. In addition, performance‐optimized gradient microstructures can be produced by sequential casting of slurries with different compositions, resulting in dense and flat phase‐pure cathodes without unwanted ion interdiffusion or secondary phase formation. Freestanding cathodes with a thickness of 85 µm, a relative density of 95%, and an industrial relevant LCO loading of 15 mg show an initial capacity of 82 mAh g−1 (63% of the theoretical capacity of LCO) in a solid‐state cell with Li metal anodes, which is comparable to conventional LCO/LLZO cathodes and can be further improved in the future.

Published
2024
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4. Preparation and electrochemical properties of Li6La3Zr0.7Ti0.3Ta0.5Sb0.5O12 high-entropy Li-garnet solid electrolyte

Author

Ruijie Ye, Yin-Ying Ting, Enkhtsetseg Dashjav, Qianli Ma, Sou Taminato, Daisuke Mori, Nobuyuki Imanishi, Piotr M. Kowalski, Michael H. Eikerling, Payam Kaghazchi, Martin Finsterbusch, and Olivier Guillon

Subjects
garnet, high entropy, solid electrolyte, ionic conductor, first-principle, DFT, General Works
Abstract

Garnet-type solid electrolytes stand out as promising Li-ion conductors for the next-generation batteries. It has been demonstrated that the inherent properties of garnets can be tailored by introducing various dopants into their crystal structures. Recently, there has been a growing interest in the concept of high entropy stabilization for materials design. In this study, we synthesized high-entropy garnets denoted as Li6La3Zr0.7Ti0.3Ta0.5Sb0.5O12 (LLZTTSO), wherein Ti, Sb, and Ta occupy the Zr site. The formation of the cubic garnet phase in LLZTTSO was confirmed through X-ray diffraction (XRD), and the resulting lattice parameter agreed with predictions made using computational methods. Despite the substantial porosity (relative density 80.6%) attributed to the low sintering temperature, LLZTTSO exhibits a bulk ionic conductivity of 0.099 mS cm−1 at 25°C, and a total ionic conductivity of 0.088 mS cm−1, accompanied by an activation energy of 0.497 eV. Furthermore, LLZTTSO demonstrates a critical current density of 0.275 mA cm−2 at 25°C, showcasing its potential even without any interfacial modification.

Published
2024
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5. Thermodynamic and structural characterization of high-entropy garnet electrolytes for all-solid-state battery

Author

Yin-Ying Ting, Ruijie Ye, Enkhtsetseg Dashjav, Qianli Ma, Sou Taminato, Daisuke Mori, Nobuyuki Imanishi, Martin Finsterbusch, Michael H. Eikerling, Olivier Guillon, Payam Kaghazchi, and Piotr M. Kowalski

Subjects
solid electrolyte, garnet, ionic conductor, DFT, high-entropy, solid-state lithium battery, General Works
Abstract

This study explores multi-component garnet-based materials as solid electrolytes for all-solid-state lithium batteries. Through a combination of computational and experimental approaches, we investigate the thermodynamic and structural properties of lithium lanthanum zirconium oxide garnets doped with various elements. Applying density functional theory, the influence of dopants on the thermodynamic stability of these garnets was studied. Probable atomic configurations and their impact on materials’ properties were investigated with the focus on understanding the influence of these configurations on structural stability, phase preference, and ionic conductivity. In addition to the computational study, series of cubic-phase garnet compounds were synthesized and their electrochemical performance was evaluated experimentally. Our findings reveal that the stability of cubic phase in doped Li-garnets is primarily governed by enthalpy, with configurational entropy playing a secondary role. Moreover, we establish that the increased number of doping elements significantly enhances the cubic phase’s stability. This in-depth understanding of materials’ properties at atomic level establishes the basis for optimizing high-entropy ceramics, contributing significantly to the advancement of solid-state lithium batteries and other applications requiring innovative material solutions.

Published
2024
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6. Promoting densification and grain growth of BaCe0.65Zr0.2Y0.15O3-δ

Author

Wenyu Zhou, Fanlin Zeng, Jürgen Malzbender, Hartmut Schlenz, Wendelin Deibert, Dmitry Sergeev, Ivan Povstugar, Ruth Schwaiger, Arian Nijmeijer, Michael Müller, Olivier Guillon, and Wilhelm Albert Meulenberg

Subjects
Proton conductor, Perovskite, NiO additive, Sintering, Densification, Grain growth, Mining engineering. Metallurgy, TN1-997
Abstract

BaCe0.65Zr0.2Y0.15O3-δ (BCZ20Y15) has raised great interest due to its good protonic conductivity and chemical stability. However, the sintering of the material is considerably challenged by its refractory nature. In the current work, almost fully densified single-phase BCZ20Y15 with grain sizes exceeding 10 μm was successfully fabricated by sintering at 1500 °C by using calcined powders consisting of naturally separated perovskite phases and 0.5 wt% NiO. The role of NiO as sintering aid was elucidated by Inductively Coupled Plasma Optical Emission Spectroscopy (ICP-OES) and Atom Probe Tomography (APT) methods, concerning global and local material composition. Furthermore, the mechanism leading to the promoted densification and grain growth is elucidated based on current experimental results and a comprehensive review of the literature.

Published
2023
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8. Lanthanide element variation in rare earth doped ceria – FeCo2O4 dual phase oxygen transport membranes

Author

Liudmila Fischer, Ke Ran, Christina Schmidt, Kerstin Neuhaus, Stefan Baumann, Patrick Behr, Joachim Mayer, Henny J.M. Bouwmeester, Arian Nijmeijer, Olivier Guillon, and Wilhelm A. Meulenberg

Subjects
Ceria-based somposites, Mixed ionic-electronic conductors, Dual phase oxygen transport membrane, Ceramic materials, Optimization, Microstructure, Clay industries. Ceramics. Glass, TP785-869
Abstract

The increased interest in dual-phase membrane materials for oxygen separation leads to the continuous optimization of their composition. Rare-earth doped ceria is a promising candidate as the ion-conducting phase in the membrane. Spinel-structured FeCo2O4 was investigated as an electronic conducting phase forming an additional electronic conducting perovskite-structured phase during sintering when combined with Ce1−xLnxO2−δ. The influence of rare-earth lanthanide elements, i.e., Gd and Sm, as well as their concentration, i.e. x = 0.1 and 0.2, on the final phase composition and microstructure as well as its related functional properties in particular oxygen permeation is analyzed. 20 mol.% doping of either Gd or Sm reveals a multi-phase microstructure after sintering. Moreover, segregation of Gd/Sm, iron, and cobalt is found at the ceria-ceria grain boundaries in Ce0.8Sm0.2O2−δ- and Ce0.9Gd0.1O2−δ-based composites. In contrast, 10 mol.% Gd–doping leads to a dual-phase membrane material without the formation of any other phase. In all cases, the percolation threshold is reached at approx. 20 vol% of the electron-conducting phase in the system leading to similar maximum permeation rates determined by the ionic conductivity of the ceria phase.

Published
2024
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9. Direct Recycling of Hot‐Deformed Nd–Fe–B Magnet Scrap by Field‐Assisted Sintering Technology

Author

Monica Keszler, Felix Grosswendt, Anna-Caroline Assmann, Martin Krengel, Fernando Maccari, Oliver Gutfleisch, Doris Sebold, Olivier Guillon, Sebastian Weber, and Martin Bram

Subjects
circular economy, field assisted sintering, functional materials, permanent magnets, rare earth elements, recycling, Environmental technology. Sanitary engineering, TD1-1066, Renewable energy sources, TJ807-830
Abstract

Recycling of Nd–Fe–B magnets is an ongoing challenge regarding circular economy. State‐of‐the‐art magnet production methods, such as hot deformation, have limitations with respect to direct recycling of magnet scrap particles that differ from pristine melt‐spun Nd–Fe–B powder. Recent work has shown that a combination of presintering by field‐assisted sintering technology/spark plasma sintering (FAST/SPS) and hot deformation by flash spark plasma sintering (flash SPS) has the potential to directly produce Nd–Fe–B magnets from 100% scrap material. Both processes have the capability to adjust and monitor process parameters closely, resulting in recycled magnets with properties similar to commercial magnets but made directly from crushed and recycled Nd–Fe–B powder that partially or completely replaces pristine melt‐spun Nd–Fe–B powder. Herein, a systematic study is done inserting recycled magnet particles into a flash SPS deformed magnet, considering the effects of different weight percentages of scrap material of varied particle size fractions. In some cases, coercivity HcJ of >1400 kAm−1 and remanence Br of 1.1 T can be achieved with 20 wt% scrap material. The relationship between particle size fraction, oxygen uptake, and percentage of recyclate in a final magnet are all explored and discussed with respect to magnets made from pristine material.

Published
2024
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10. Pressureless all‐solid‐state Na/S batteries with self‐supporting Na5YSi4O12 scaffolds

Author

Aikai Yang, Ruijie Ye, Huimin Song, Qiongqiong Lu, Xingchao Wang, Enkhtsetseg Dashjav, Kai Yao, Daniel Grüner, Qianli Ma, Frank Tietz, and Olivier Guillon

Subjects
Na/S batteries, Na5YSi4O12, scaffold, solid‐state electrolytes, tape casting, Production of electric energy or power. Powerplants. Central stations, TK1001-1841
Abstract

Abstract The development of reliable and affordable all‐solid‐state sodium metal batteries (ASS‐SMBs) requires suitable solid‐state electrolytes with cost‐efficient processing and stabilized electrode/electrolyte interfaces. Here, an integrated porous/dense/porous Na5YSi4O12 (NYS) trilayered scaffold is designed and fabricated by tape casting using aqueous slurries. In this template‐based NYS scaffold, the dense layer in the middle serves as a separator and the porous layers on both sides accommodate the active materials with their volume changes during the charge/discharge processes, increasing the contact area and thus enhancing the utilization rate and homogenizing the current distribution. The Na/NYS/Na symmetric cells with the Pb‐coated NYS scaffold exhibit significantly reduced interfacial impedance and superior critical current density of up to 3.0 mA cm−2 against Na metal owing to enhanced wettability. Furthermore, the assembled Na/NYS/S full cells operated without external pressure at room temperature showed a high initial discharge capacity of 970 mAh g−1 and good cycling stability with a capacity of 600 mAh g−1 after 150 cycles (based on the mass of sulfur). This approach paves the way for the realization of economical and practical ASS‐SMBs from the perspective of ceramic manufacturing.

Published
2023
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11. Enhanced room-temperature Na+ ionic conductivity in Na4.92Y0.92Zr0.08Si4O12

Author

Aikai Yang, Kai Yao, Mareen Schaller, Enkhtsetseg Dashjav, Hang Li, Shuo Zhao, Qiu Zhang, Martin Etter, Xingchen Shen, Huimin Song, Qiongqiong Lu, Ruijie Ye, Igor Moudrakovski, Quanquan Pang, Sylvio Indris, Xingchao Wang, Qianli Ma, Frank Tietz, Jun Chen, and Olivier Guillon

Subjects
Solid-state electrolytes, Sodium superionic conductors, Na4.92Y0.92Zr0.08Si4O12, High conductivity, Ultra-wide electrochemical window, Mechanical engineering and machinery, TJ1-1570, Electronics, TK7800-8360
Abstract

Developing cost-effective and reliable solid-state sodium batteries with superior performance is crucial for stationary energy storage. A key component in facilitating their application is a solid-state electrolyte with high conductivity and stability. Herein, we employed aliovalent cation substitution to enhance ionic conductivity while preserving the crystal structure. Optimized substitution of Y3+ with Zr4+ in Na5YSi4O12 introduced Na+ ​ion vacancies, resulting in high bulk and total conductivities of up to 6.5 and 3.3 ​mS ​cm−1, respectively, at room temperature with the composition Na4.92Y0.92Zr0.08Si4O12 (NYZS). NYZS shows exceptional electrochemical stability (up to 10 ​V vs. Na+/Na), favorable interfacial compatibility with Na, and an excellent critical current density of 2.4 ​mA ​cm−2. The enhanced conductivity of Na+ ​ions in NYZS was elucidated using solid-state nuclear magnetic resonance techniques and theoretical simulations, revealing two migration routes facilitated by the synergistic effect of increased Na+ ​ion vacancies and improved chemical environment due to Zr4+ substitution. NYZS extends the list of suitable solid-state electrolytes and enables the facile synthesis of stable, low-cost Na+ ion silicate electrolytes.

Published
2023
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12. Fundamental investigations on the sodium-ion transport properties of mixed polyanion solid-state battery electrolytes

Author

Zeyu Deng, Tara P. Mishra, Eunike Mahayoni, Qianli Ma, Aaron Jue Kang Tieu, Olivier Guillon, Jean-Noël Chotard, Vincent Seznec, Anthony K. Cheetham, Christian Masquelier, Gopalakrishnan Sai Gautam, and Pieremanuele Canepa

Subjects
Science
Abstract

Battery solid-state electrolytes rely on mixed polyanion networks to attain high ionic conductivities. Here, the authors investigate the effect of polyanion mixing on the solid-state electrolyte ion conductivity via theoretical calculations and electrochemical measurements.

Published
2022
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13. NaSICON-type solid-state Li+ ion conductors with partial polyanionic substitution of phosphate with silicate

Author

Asmaa Loutati, Olivier Guillon, Frank Tietz, and Dina Fattakhova-Rohlfing

Subjects
Ceramics, Li solid electrolyte, NaSICON, Anion substitution, Impedance spectroscopy, Ionic conductivity, Clay industries. Ceramics. Glass, TP785-869
Abstract

The increasing demand for safe energy storage has led to intensive investigations of solid-state Li+-ion conductors in the Li2O-M2O3–ZrO2–SiO2–P2O5 system. As a continuation of the cation substitution in this system, which we reported on very recently, a study of the impact of polyanionic substitutions on ionic conductivity was carried out here in two series, Li3+xSc2SixP3-xO12 (0 ≤ x ≤ 0.6) and Li1.2+xSc0.2Zr1.8SixP3-xO12 (0.3 ≤ x ≤ 2.8), with the aim of increasing ionic conductivity, determing the phase stability, and optimizing the processing conditions – especially decreasing the sintering temperatures – depending on the level of substitution.The polyanionic substitution, i.e. the substitution of (PO4)3- with (SiO4)4-, in the Li2O–Sc2O3–ZrO2–SiO2–P2O5 system revealed that a) the sintering temperature can effectively be reduced, b) the presence of zirconium can limit the evaporation of lithium species even at high sintering temperatures, c) the purity of the NaSICON materials has a strong influence on the grain boundary resistance, and therefore on the ionic conductivity, and d) the silicate substitution in Li3+xSc2SixP3-xO12 (0 ≤ x ≤ 0.6) stabilized the monoclinic polymorph (space group P21/n) with an enhanced total ionic conductivity at 25 °C from 6.5 × 10−7 S cm−1 to 1.2 × 10−5 S cm−1 for x = 0 to x = 0.15, respectively, exhibiting the highest ionic conductivity at 25 °C among the compositions investigated.

Published
2022
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14. Ceramic materials for energy conversion and storage: A perspective

Author

Olivier Guillon

Subjects
energy conversion, energy storage, materials design, processing, testing, Clay industries. Ceramics. Glass, TP785-869
Abstract

Abstract Advanced ceramic materials with tailored properties are at the core of established and emerging energy technologies. Applications encompass high‐temperature power generation, energy harvesting, and electrochemical conversion and storage. New opportunities for material design, the importance of processing and material integration, and the need for long‐term testing under realistic conditions are highlighted in the present perspective.

Published
2021
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15. Role of Fe/Co Ratio in Dual Phase Ce0.8Gd0.2O2−δ–Fe3−xCoxO4 Composites for Oxygen Separation

Author

Liudmila Fischer, Ke Ran, Christina Schmidt, Kerstin Neuhaus, Stefan Baumann, Patrick Behr, Joachim Mayer, Henny J. M. Bouwmeester, Arian Nijmeijer, Olivier Guillon, and Wilhelm A. Meulenberg

Subjects
mixed ionic-electronic conductors, dual phase oxygen transport membrane, ceramic materials, optimization, microstructure, spinel-type ferrite, Chemical technology, TP1-1185, Chemical engineering, TP155-156
Abstract

Dual-phase membranes are increasingly attracting attention as a solution for developing stable oxygen permeation membranes. Ce0.8Gd0.2O2−δ–Fe3−xCoxO4 (CGO-F(3−x)CxO) composites are one group of promising candidates. This study aims to understand the effect of the Fe/Co-ratio, i.e., x = 0, 1, 2, and 3 in Fe3−xCoxO4, on microstructure evolution and performance of the composite. The samples were prepared using the solid-state reactive sintering method (SSRS) to induce phase interactions, which determines the final composite microstructure. The Fe/Co ratio in the spinel structure was found to be a crucial factor in determining phase evolution, microstructure, and permeation of the material. Microstructure analysis showed that all iron-free composites had a dual-phase structure after sintering. In contrast, iron-containing composites formed additional phases with a spinel or garnet structure which likely contributed to electronic conductivity. The presence of both cations resulted in better performance than that of pure iron or cobalt oxides. This demonstrated that both types of cations were necessary to form a composite structure, which then allowed sufficient percolation of robust electronic and ionic conducting pathways. The maximum oxygen flux is jO2 = 0.16 and 0.11 mL/cm2·s at 1000 °C and 850 °C, respectively, of the 85CGO-FC2O composite, which is comparable oxygen permeation flux reported previously.

Published
2023
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16. A microwave‐based one‐pot process for homogeneous surface coating: improved electrochemical performance of Li(Ni1/3Mn1/3Co1/3)O2 with a nano‐scaled ZnO:Al layer

Author

Michael Wolff, Sandra Lobe, Christian Dellen, Sven Uhlenbruck, Caue Ribeiro, Xavier H. Guichard, Markus Niederberger, Ardavan Makvandi, Martin Peterlechner, Gerhard Wilde, Dina Fattakhova‐Rohlfing, and Olivier Guillon

Subjects
cathode materials, lithium‐ion batteries, microwave synthesis, sol–gel method, ultrathin coating, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Abstract In this article, a versatile process based on microwave‐assisted sol–gel synthesis is introduced in order to apply a surface coating on cathode material for lithium‐ion batteries. Here, a nano‐scaled ZnO:Al (AZO) layer is coated homogeneously onto Li(Ni1/3Mn1/3Co1/3)O2 (NMC111) powder at temperatures below 210°C within a few minutes. In contrast to other wet‐chemical coating techniques, the method described here is conducted in a one‐pot reaction and does not require a post‐annealing step at elevated temperatures. Investigations via high resolution transmission electron microscopy (HR‐TEM), scanning transmission electron microscopy (STEM) and inductively‐coupled plasma optical emission spectroscopy (ICP‐OES) promote a thorough understanding of coating microstructure and quality in dependence of reaction temperature, duration and precursor concentration. The AZO protective coating on NMC111 significantly reduces capacity fading during cycling in the voltage range of 3.0‐4.5 V. Furthermore, applying optimal quantities of the coating agent on NMC111 lead to enhanced specific capacities compared to the uncoated material.

Published
2021
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17. Performance study of asymmetric oxygen transport membranes with vertically channelled pores by phase inversion tape casting

Author

Yang Liu, Kai Wilkner, Unoaku Victoria Unije, Stefan Baumann, Robert Mücke, Falk Schulze-Küppers, and Olivier Guillon

Subjects
Phase inversion tape casting, Channelled pores, Permeation rate, Oxygen transport membranes, Clay industries. Ceramics. Glass, TP785-869
Abstract

Asymmetric oxygen transport membranes have been extensively studied revealing the importance of the support porosity. In this study, asymmetric membranes with vertically channelled pores were prepared from Ba0.5Sr0.5(Co0.8Fe0.2)0.97Zr0.03O3-δ (BSCF-Z) by phase inversion tape casting. The rate-limiting effects of the membrane layer thickness, the support structure, and the activation layers were thoroughly analysed. This entails comparing the permeation rate of the samples with the membrane layer on different sides of the channelled supports. Pore tortuosity and computed permeability were evaluated from 3D-X-ray computed tomography and compared to previously reported asymmetric membranes prepared by tape-casting and freeze-drying. Due to a lower pore tortuosity, the channelled supports have an advantage in gas transport over the tape cast and freeze cast supports. However, this is compensated by a thicker membrane layer (∼54 μm) resulting in similar performance compared to the thinner membrane layers (∼20 μm) with freeze cast and tape cast supports.

Published
2022
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18. Innovative Tungsten Coatings for an Application in Modern and Future Fusion Devices

Author

Tom Keller, Andrey Litnovsky, Georg Mauer, Christian Linsmeier, and Olivier Guillon

Subjects
tungsten, low-pressure plasma spraying, divertor materials, plasma-facing components, Mining engineering. Metallurgy, TN1-997
Abstract

Tungsten is foreseen presently as the plasma-facing material for divertors in fusion power plants. In order to achieve durable operation of divertors of current fusion reactors, an efficient way of maintaining the divertor functionality is needed. A system capable of in situ tungsten coating of the divertor via low-pressure plasma spraying was proposed to maintain the divertor integrity. In this work, tungsten was deposited on NB31 carbon fibre composite substrates using the low-pressure plasma spraying technology to evaluate the feasibility of this technique. The thickness, porosity, composition, adhesion, and microstructure of the coatings were investigated by scanning electron microscopy image analysis and energy dispersive spectroscopy. Based on the initial results, the spray parameters were iteratively improved in a campaign-based study. The coatings exhibited improving properties through an adjusting of the carrier gas flow, the scanning speed, and the spray distance. By lowering the carrier gas flow, the porosity of the coatings was reduced, resulting in coatings of 98% bulk density. Adjusting the carrier gas flow reduced the amount of semi-molten particles in the coatings significantly. A decrease in both scanning speed and spray distance increased the substrate’s temperature, which led to better adhesion and porosity.

Published
2023
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19. Towards In-Situ Electron Microscopy Studies of Flash Sintering

Author

Danny Schwarzbach, Jesus Gonzalez-Julian, Olivier Guillon, Vladimir Roddatis, and Cynthia A. Volkert

Subjects
ZnO, flash, sintering, field assisted sintering, densification, electric induced, green body, oxide ceramic powders, thin films, Technology, Chemical technology, TP1-1185
Abstract

Flash sintering, a special case of electric field-assisted sintering, results in accelerated densification at lower temperatures than conventional sintering methods. However, the mechanisms remain elusive despite the wide application potential. In-situ electron microscopy studies reveal shrinkage of ZnO green bodies due to both heating and heating/biasing but show no obvious effect of the current on the behavior. In contrast, thin epitaxial ZnO films deposited on an Al2O3 substrate undergo a clear flash event during in-situ voltage application in the TEM, providing the first observation of flash sintering of a thin film. The specimen was captured in the high conductivity state where grain boundary motion was observed. The microscopic origins of the high conductivity state could not be detected, but may have the same underlying physical origin as the high conductivity memristive state.

Published
2019
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21. The Development of New Perovskite-Type Oxygen Transport Membranes Using Machine Learning

Author

Hartmut Schlenz, Stefan Baumann, Wilhelm Albert Meulenberg, and Olivier Guillon

Subjects
ceramic, perovskite, oxygen separation membrane, mixed ionic-electronic conducting membrane MIEC, valence bond calculations, machine learning, Crystallography, QD901-999
Abstract

The aim of this work is to predict suitable chemical compositions for the development of new ceramic oxygen gas separation membranes, avoiding doping with toxic cobalt or expensive rare earths. For this purpose, we have chosen the system Sr1−xBax(Ti1−y−zVyFez)O3−δ (cubic perovskite-type phases). We have evaluated available experimental data, determined missing crystallographic information using bond-valence modeling and programmed a Python code to be able to generate training data sets for property predictions using machine learning. Indeed, suitable compositions of cubic perovskite-type phases can be predicted in this way, allowing for larger electronic conductivities of up to σe = 1.6 S/cm and oxygen conductivities of up to σi = 0.008 S/cm at T = 1173 K and an oxygen partial pressure pO2 = 10−15 bar, thus enabling practical applications.

Published
2022
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22. Co-Sintering Study of Na0.67[Ni0.1Fe0.1Mn0.8]O2 and NaSICON Electrolyte–Paving the way to High Energy Density All-Solid-State Batteries

Author

Gerald Dück, Sahir Naqash, Martin Finsterbusch, Uwe Breuer, Olivier Guillon, and Dina Fattakhova-Rohlfing

Subjects
sodium, NASICON, solid electrolyte, solid-state-batteries, composite cathode, General Works
Abstract

Sodium is a promising candidate for stationary storage applications, especially when the demand for lithium-ion batteries increases due to electromobility applications. Even though its energy density is lower, Na-ion technology is estimated to lead to a cost reduction of 30% compared to Li-ion technology. To improve safety as well as energy density, Na-based all-solid-state-batteries featuring solid electrolytes such as beta-alumina and sodium superionic conductors and cathode materials such as Na3V2(PO4)3 and NaxCoO2 have been developed over the past years. However, the biggest challenge are mixed cathodes with highly conductive interfaces, especially when co-sintering the materials. For example, a promising sodium superionic conductor type Na3Zr2Si2PO12 electrolyte sinters at 1,250°C, whereas the corresponding Na3V2PO12 cathode decomposes at temperatures higher than 900°C, posing a bottleneck. Thus in this paper, we synthesized Na0.62 [Ni0.10Fe0.10Mn0.80]O2 as cathode material for all-solid-state sodium-ion batteries via a relatively cheap and easy solution-assisted solid state reaction processing route. The thermal investigations of the pure cathode material found no degradation up to 1,260°C, making it a perfect match for Na3.4Zr2Si2.4P0.6O12 electrolyte. In our aim to produce a co-sintered mixed cathode, electron microscopy investigation showed a highly dense microstructure and the elemental mapping performed via energy dispersive X-ray spectroscopy and secondary ion mass spectrometry confirm that Na3.4Zr2Si2.4P0.6O12 and Na0.62 [Ni0.10Fe0.10Mn0.80]O2 do not react during sintering. However, the active cathode material forms a sodium rich and a sodium deficient phase which needs further investigation to understand the origin and its impact on the electrochemical performance.

Published
2021
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23. Processing and oxidation response of Cr2AlC MAX-phase composites containing ceramic fibers

Author

Teresa Go, Robert Vaßen, Olivier Guillon, and Jesus Gonzalez-Julian

Subjects
MAX phases, Cr2AlC, Oxidation response, Ceramic fibers, CMC, Clay industries. Ceramics. Glass, TP785-869
Abstract

Three different ceramic matrix composites (CMCs) were produced using Cr2AlC as a matrix, and carbon, SiC and Al2O3 short fibers as a secondary phase. Cr2AlC powders were synthesized by solid-state reaction, followed by mixing with the fibers, and full densification using a field-assisted sintering technique. Of the three different fiber types, Carbon fibers reacted strongly with Cr2AlC, while the reaction with SiC fibers was more limited and alumina fibers didn’t show any reaction. Oxidation tests of the monolithic Cr2AlC and the composites were performed by thermogravimetric analysis. An alumina layer formed at 1000 ​°C on every sample, well attached and worked as a good oxidation barrier. Under realistic conditions using a burner rig for cyclic oxidation at 1200 ​°C for 500 cycles, the oxidation resistance of the alumina fiber CMC is good, as no defects or degradation are visible and the alumina layer is well attached.

Published
2021
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24. A Data-Driven Framework for the Accelerated Discovery of CO2 Reduction Electrocatalysts

Author

Ali Malek, Qianpu Wang, Stefan Baumann, Olivier Guillon, Michael Eikerling, and Kourosh Malek

Subjects
CO2 reduction, high and low temperature, machine learning, artificial intelligence, materials discovery, data analytics, General Works
Abstract

Searching for next-generation electrocatalyst materials for electrochemical energy technologies is a time-consuming and expensive process, even if it is enabled by high-throughput experimentation and extensive first-principle calculations. In particular, the development of more active, selective and stable electrocatalysts for the CO2 reduction reaction remains tedious and challenging. Here, we introduce a material recommendation and screening framework, and demonstrate its capabilities for certain classes of electrocatalyst materials for low or high-temperature CO2 reduction. The framework utilizes high-level technical targets, advanced data extraction, and categorization paths, and it recommends the most viable materials identified using data analytics and property-matching algorithms. Results reveal relevant correlations that govern catalyst performance under low and high-temperature conditions.

Published
2021
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25. Sensitivity of Material, Microstructure and Operational Parameters on the Performance of Asymmetric Oxygen Transport Membranes: Guidance from Modeling

Author

Kai Wilkner, Robert Mücke, Stefan Baumann, Wilhelm Albert Meulenberg, and Olivier Guillon

Subjects
binary friction model, oxygen transport membrane, porous media, MIEC, supported membrane, Chemical technology, TP1-1185, Chemical engineering, TP155-156
Abstract

Oxygen transport membranes can enable a wide range of efficient energy and industrial applications. One goal of development is to maximize the performance by the improvement of the material, microstructural properties and operational conditions. However, the complexity of the transportation processes taking place in such commonly asymmetric membranes impedes the identification of the parameters to improve them. In this work, we present a sensitivity study that allows identification of these parameters. It is based on a 1D transport model that includes surface exchange, ionic and electronic transport inside the dense membrane, as well as binary diffusion, Knudsen diffusion and viscous flux inside the porous support. A support limitation factor is defined and its dependency on the membrane conductivity is shown. For materials with very high ambipolar conductivity the transport is limited by the porous support (in particular the pore tortuosity), whereas for materials with low ambipolar conductivity the transport is limited by the dense membrane. Moreover, the influence of total pressure and related oxygen partial pressures in the gas phase at the membrane’s surfaces was revealed to be significant, which has been neglected so far in permeation test setups reported in the literature. In addition, the accuracy of each parameter’s experimental determination is discussed. The model is well-suited to guiding experimentalists in developing high-performance gas separation membranes.

Published
2022
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26. Metal-Supported Solid Oxide Fuel Cells with Exceptionally High Power Density for Range Extender Systems

Author

David Udomsilp, Jürgen Rechberger, Raphael Neubauer, Cornelia Bischof, Florian Thaler, Wolfgang Schafbauer, Norbert H. Menzler, Lambertus G.J. de Haart, Andreas Nenning, Alexander K. Opitz, Olivier Guillon, and Martin Bram

Subjects
metal-supported solide oxide fuel cells, range extender, electric vehicles, benchmark SOFC performance, modeling of electrochemical performance, impedance spectroscopy, Physics, QC1-999
Abstract

Summary: Solid oxide fuel cells (SOFCs) exhibit potential to become a key technology for future clean energy systems. The metal-supported SOFC exhibits decisive strengths like fast start-up capability, mechanical robustness, and acceptable cost, making it the concept of choice for mobile applications. As a promising example, SOFC-powered range extenders for electric vehicles offer fast refueling and significantly increased driving range, while lowering size, weight, and the cost of the vehicle’s battery. Here, we report the development of a metal-supported SOFC aiming at exceptionally high power density. A knowledge-based improvement of all electrochemically active cell components enables a performance increase up to a factor of 10 and demonstrates the effectiveness of target-oriented optimization of processing and microstructure. Ultimately, enhanced cells meet the industrial performance target by providing a current density of 2.8 A × cm−2 at 650°C and 0.7 V, setting a benchmark for SOFC performance.

Published
2020
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27. Enhanced metal exsolution at the non-polar (001) surfaces of multi-faceted epitaxial thin films

Author

Moritz L Weber, Moritz Kindelmann, Egbert Wessel, Alexandros Sarantopoulos, Norbert H Menzler, Regina Dittmann, Rainer Waser, Olivier Guillon, Christian Lenser, and Felix Gunkel

Subjects
metal exsolution, nanoparticles, catalysis, surface orientation, epitaxy, surface reconstruction, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Renewable energy sources, TJ807-830
Abstract

Metal exsolution is a dynamic process driven under a reducing atmosphere and at elevated temperatures that results in the self-assembly of nanoparticles at the surface of complex perovskite catalysts. The nanoparticle characteristics of metal exsolution catalysts can be subject to considerable inhomogeneity, and the anisotropic surface properties of ceramic oxides have been identified to have a major influence on the exsolution behavior. We systematically reveal the orientation-dependent anisotropy of the exsolution behavior of Ni in SrTi _0.9 Nb _0.05 Ni _0.05 O _3−δ using multi-faceted epitaxial thin films that represent a material system with properties in between functional ceramics and single-crystalline perovskite thin film model systems. Using an approach of combined orientation mapping and surface imaging we study the exsolution behavior with particular focus on the initial exsolution response, i.e. after short annealing times. We find orientation-specific variations in the surface morphology of the thin film facets. In the as-prepared state, surface reconstructions cause the formation of patterned surface structures for all thin film facets apart from (001) surfaces, which exhibit a plain surface morphology as well as an enhanced exsolution response. Surface reconstructions and their inherent energy landscape may hence cause an additional energy barrier for the exsolution reaction that results in orientation-dependent differences in the exsolution kinetics.

Published
2022
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28. Improving the W Coating Uniformity by a COMSOL Model-Based CVD Parameter Study for Denser Wf/W Composites

Author

Leonard Raumann, Jan Willem Coenen, Johann Riesch, Yiran Mao, Daniel Schwalenberg, Hanns Gietl, Christian Linsmeier, and Olivier Guillon

Subjects
tungsten, fiber composite, chemical vapor deposition, modeling, parameter study, Mining engineering. Metallurgy, TN1-997
Abstract

Tungsten (W) has the unique combination of excellent thermal properties, low sputter yield, low hydrogen retention, and acceptable activation. Therefore, W is presently the main candidate for the first wall and armor material for future fusion devices. However, its intrinsic brittleness and its embrittlement during operation bears the risk of a sudden and catastrophic component failure. As a countermeasure, tungsten fiber-reinforced tungsten (Wf/W) composites exhibiting extrinsic toughening are being developed. A possible Wf/W production route is chemical vapor deposition (CVD) by reducing WF6 with H2 on heated W fabrics. The challenge here is that the growing CVD-W can seal gaseous domains leading to strength reducing pores. In previous work, CVD models for Wf/W synthesis were developed with COMSOL Multiphysics and validated experimentally. In the present article, these models were applied to conduct a parameter study to optimize the coating uniformity, the relative density, the WF6 demand, and the process time. A low temperature and a low total pressure increase the process time, but in return lead to very uniform W layers at the micro and macro scales and thus to an optimized relative density of the Wf/W composite. High H2 and low WF6 gas flow rates lead to a slightly shorter process time and an improved coating uniformity as long as WF6 is not depleted, which can be avoided by applying the presented reactor model.

Published
2021
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29. Recycling Strategies for Ceramic All-Solid-State Batteries—Part I: Study on Possible Treatments in Contrast to Li-Ion Battery Recycling

Author

Lilian Schwich, Michael Küpers, Martin Finsterbusch, Andrea Schreiber, Dina Fattakhova-Rohlfing, Olivier Guillon, and Bernd Friedrich

Subjects
battery recycling, all-solid-state batteries, metallurgical recycling, metal recovery, recycling efficiency, Mining engineering. Metallurgy, TN1-997
Abstract

In the coming years, the demand for safe electrical energy storage devices with high energy density will increase drastically due to the electrification of the transportation sector and the need for stationary storage for renewable energies. Advanced battery concepts like all-solid-state batteries (ASBs) are considered one of the most promising candidates for future energy storage technologies. They offer several advantages over conventional Lithium-Ion Batteries (LIBs), especially with regard to stability, safety, and energy density. Hardly any recycling studies have been conducted, yet, but such examinations will play an important role when considering raw materials supply, sustainability of battery systems, CO2 footprint, and general strive towards a circular economy. Although different methods for recycling LIBs are already available, the transferability to ASBs is not straightforward due to differences in used materials and fabrication technologies, even if the chemistry does not change (e.g., Li-intercalation cathodes). Challenges in terms of the ceramic nature of the cell components and thus the necessity for specific recycling strategies are investigated here for the first time. As a major result, a recycling route based on inert shredding, a subsequent thermal treatment, and a sorting step is suggested, and transferring the extracted black mass to a dedicated hydrometallurgical recycling process is proposed. The hydrometallurgical approach is split into two scenarios differing in terms of solubility of the ASB-battery components. Hence, developing a full recycling concept is reached by this study, which will be experimentally examined in future research.

Published
2020
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30. Coefficients of Thermal Expansion of Al- and Y-Substituted NaSICON Solid Solution Na3+2xAlxYxZr2−2xSi2PO12

Author

Sahir Naqash, Marie-Theres Gerhards, Frank Tietz, and Olivier Guillon

Subjects
thermal expansion coefficient, dilatometry, NASICON, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Industrial electrochemistry, TP250-261
Abstract

Because of an increasing interest in NaSICON materials as electrolyte materials in all-solid state sodium batteries, their thermal expansion was investigated in this study. The thermal expansion coefficient (CTE) of the Al and Y-substituted NaSICON compositions Na3+2xAlxYxZr2−2xSi2PO12 with 0 ≤ x ≤ 0.3 was obtained by dilatometry and compared to the CTE derived from the lattice parameters using high-temperature X-ray diffraction. The difference in CTE obtained from techniques, the influence of sodium content and central metal cation on CTE, as well as other observations such as phase changes are described and rationalized.

Published
2018
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31. Improved compaction of ZnO nano-powder triggered by the presence of acetate and its effect on sintering

Author

Benjamin Dargatz, Jesus Gonzalez-Julian, and Olivier Guillon

Subjects
sintering, green body processing, nano-powder, zinc oxide, water, zinc acetate, zero radial shrinkage, Materials of engineering and construction. Mechanics of materials, TA401-492, Biotechnology, TP248.13-248.65
Abstract

The retention of nanocrystallinity in dense ceramic materials is still a challenge, even with the application of external pressure during sintering. The compaction behavior of high purity and acetate enriched zinc oxide (ZnO) nano-powders was investigated. It was found that acetate in combination with water plays a key role during the compaction into green bodies at moderate temperatures. Application of constant pressure resulted in a homogeneous green body with superior packing density (86% of theoretical value) at moderate temperature (85 °C) in the presence of water. In contrast, no improvement in density could be achieved if pure ZnO powder was used. This compaction behavior offers superior packing of the particles, resulting in a high relative density of the consolidated compact with negligible coarsening. Dissolution accompanying creep diffusion based matter transport is suggested to strongly support reorientation of ZnO particles towards densities beyond the theoretical limit for packing of ideal monosized spheres. Finally, the sintering trajectory reveals that grain growth is retarded compared to conventional processing up to 90% of theoretical density. Moreover, nearly no radial shrinkage was observed after sinter-forging for bodies performed with this advanced processing method.

Published
2015
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32. Comparison of the Simplification of the Pressure Profiles Solving the Binary Friction Model for Asymmetric Membranes

Author

Unoaku Victoria Unije, Robert Mücke, Stefan Baumann, and Olivier Guillon

Subjects
binary friction model, oxygen transport membrane, porous structure, MIEC, micro porous media, CFD, Chemical technology, TP1-1185, Chemical engineering, TP155-156
Abstract

The gas flow through porous media including that of multiple species is frequently described by the binary friction model (BFM) considering the binary diffusion, Knudsen diffusion, and viscous flow. Therefore, a numerical simulation was performed on a microporous support of an asymmetric oxygen transport membrane. As its exact numerical solution is complicated and not always possible, the results of two different levels of simplification of the pressure profiles within the porous support are compared to the exact numerical solution. The simplification using a constant pressure equal to the gas pressure outside the support leads to a deviation by up to 0.45 mL·min−1·cm−2 from the exact solution under certain operating condition. A different simplification using a constant pressure averaged between the outside of the support and the support/membrane interface reduces this deviation to zero. Therefore, this is a useful measure to reduce computational efforts when implementing the Binary Friction Model in computational fluid dynamics simulations.

Published
2017
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33. Recycling and Reuse Strategies for Ceramic Components of Solid Oxide Cells

Author

Stephan Sarner, Norbert H. Menzler, Andrea Hilgers, and Olivier Guillon

Subjects
ddc:540, General Medicine
Abstract

The integration of solid oxide cells (SOCs) into circular economy is crucial to enable efficient preservation of critical and high-cost resources such as rare earth elements, cobalt, and nickel used in conventional SOC applications. Based on the fuel electrode-supported cell (FESC) design, a semi-closed loop recycling approach was applied for cell material from CeramTec/Forschungszentrum Jülich. We show that more than 85 wt% of the ceramic components can be successfully reprocessed to new fuel electrode-based substrate that can be further used in cell production. Reprocessing of sintered bodies requires a multi-stage procedure. Increasing the amount of recyclate in the substrate leads to changes in substrate properties such as higher porosities and reduced shrinkage.

Published
2023
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34. Analysis of Structural Degradation Effects in a Solid Oxide Fuel Cell after Long-Term Operation

Author

Christian Dellen, Samuel Tardif, Ravi Purohit, Jean-Sébastien Micha, Olivier Guillon, and Norbert H. Menzler

Subjects
General Medicine
Abstract

An in-depth post mortem analysis was conducted on cells from a stack with an operation time of 100,000 h. In doing so, the focus of the investigations was mainly on the air electrode side. By utilizing scanning electron microscopy in combination with energy dispersive X-ray spectroscopy the microstructure and the localized chemical composition was investigated. Additionally, the structural changes of the cells were analyzed by X-ray diffraction, by Raman spectroscopy, and by synchrotron-based µ-Laue diffraction measurements. The combination of these advanced analytical tools highlights changes in the structure and chemical composition on the air electrode side caused by various degradation effects after long-term operation.

Published
2023
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35. Perovskite-Based Materials As Alternative Fuel Electrodes for Solid Oxide Electrolysis Cells (SOECs)

Author

Franziska Elisabeth Winterhalder, Yousef Alizad Farzin, Olivier Guillon, Andre Weber, and Norbert H. Menzler

Subjects
General Medicine
Abstract

Perovskites show high potential as alternative fuel electrodes in solid oxide electrolysis cells (SOECs) due to their high chemical stability, high conductivity, good catalytic activity and cost-effectiveness. In this work, four perovskites (strontium-iron-niobate double perovskite (SFN), strontium-iron-titanate (STF), lanthanum-strontium-titanate (LST), and lanthanum-strontium-iron-manganese (LSFM)) were examined as fuel electrode materials for SOECs. First, the chemical stability of the perovskites in a reducing atmosphere and the reactivity between the electrode and electrolyte material were analyzed. Besides featuring good chemical stability under reducing conditions, SFN double perovskite and LST exhibit the lowest interaction with the electrolyte (yttria-stabilized zirconia, 8YSZ) after thermal treatment. The results indicate a need for a barrier layer between the tested electrode materials and the YSZ electrolyte to achieve sufficient cell performance throughout its operation in the electrolysis mode. After thoroughly evaluating all preliminary tests, STF was chosen for the first subsequent electrochemical tests. Initial impedance measurements of symmetrical electrolyte-supported cells consisting of pure STF-based electrodes with and without a barrier layer between the electrodes and the electrolyte were conducted to obtain a base for further optimization. For the 5STF fuel electrode, the obtained EIS data confirm the conclusion from the reactivity experiments. Applying a barrier layer at the 5STF fuel electrode/ electrolyte interface is needed to reduce the cell´s ohmic and polarization resistances.

Published
2023
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37. Towards economic processing of high performance garnets – case study on zero Li excess Ga-substituted LLZO

Author

Christian Schwab, Grit Häuschen, Markus Mann, Christoph Roitzheim, Olivier Guillon, Dina Fattakhova-Rohlfing, and Martin Finsterbusch

Subjects
Renewable Energy, Sustainability and the Environment, ddc:530, General Materials Science, General Chemistry
Abstract

In this processing study we systematically investigate the impact of lithium excess and dwell time on Ga-substituted LLZO:Ga and show that Li-excess during synthesis and processing is a critical parameter to obtain peak performance.

Published
2023
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38. Flash sintering behaviour of 8YSZ-NiO composites

Author

Subhadip Bhandari, Tarini Prasad Mishra, Martin Bram, Olivier Guillon, and Devinder Yadav

Subjects
ddc:670, Process Chemistry and Technology, Materials Chemistry, Ceramics and Composites, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Abstract

Flash sintering is an electric field/current assisted sintering technique, which is reported to lower the furnace temperature and to reduce sintering time significantly. In this work, we have studied the processing of 8YSZ/NiO composites by flash sintering, for the first time. Two composites, with different amount of NiO (one below the percolation limit and another one above it) were processed in two different sintering atmospheres. Constant heating rate experiments were performed to know the minimum furnace temperature required to flash sinter the samples for a given applied electric field. Subsequently, isothermal flash sintering experiments were performed at different current densities. The flash onset temperature of the composites was lower in the reducing atmosphere compared to in air. The power dissipated in stage III of the flash was strongly influenced by the composite composition and the sintering atmosphere. The extent of densification in the composites was controlled by the current density. The composites were densified up to a relative density of ∼90% in 30 s when flash sintered in air. In reducing atmosphere, there was in-situ reduction of NiO to Ni. As a result, for composites containing NiO above the percolation limit, the current preferentially flew through the in-situ formed metallic phase and there was no densification in the composite in reducing atmosphere. Phase and microstructure evolution in the composites was studied through XRD, SEM and EDS. With proper control of the electrical parameters (electric field and current density), composites with controlled porosity can be processed through flash sintering which may have applications for solid oxide fuel cells.

Published
2022
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39. Mechanical properties of BaCe0.65Zr0.2Y0.15O3- – Ce0.85Gd0.15O2- dual-phase proton-conducting material with emphasis on micro-pillar splitting

Author

Wenyu Zhou, Jürgen Malzbender, Fanlin Zeng, Wendelin Deibert, Louis Winnubst, Arian Nijmeijer, Olivier Guillon, Ruth Schwaiger, Wilhelm Albert Meulenberg, MESA+ Institute, and Inorganic Membranes

Subjects
ddc:660, Micro-pillar splitting, Materials Chemistry, Ceramics and Composites, Proton conductor, Mechanical properties, Indentation, Fracture toughness, n/a OA procedure, Dual-phase
Abstract

BaCe0.65Zr0.2Y0.15O3-δ – Ce0.85Gd0.15O2-δ (BCZ20Y15-GDC15) dual-phase material revealed potential for H2 production technologies due to its exceptional H2 permeation and chemical resistance. In this article, mechanical properties of BCZ20Y15-GDC15 dual-phase material were investigated to evaluate the mechanical behavior and develop strategies to warrant structural stability. Elastic modulus, hardness and fracture toughness values were studied using different indentation-based methods. The fracture experiments at different length-scales both revealed that the introduction of GDC15 makes the material tougher, facilitating the further design of robust and reliable components.

Published
2022
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41. Conductivity enhancement of Al- and Ta-substituted Li7La3Zr2O7 solid electrolytes by nanoparticles

Author

Olivier Guillon, Hartmut Wiggers, Yusuf Ali, Sven Uhlenbruck, Hans Orthner, Dina Fattakhova-Rohlfing, and Alexander Bauer

Subjects
Materials science, Oxide, Sintering, chemistry.chemical_element, Nanoparticle, Conductivity, Atmospheric temperature range, chemistry.chemical_compound, chemistry, Chemical engineering, Materials Chemistry, Ceramics and Composites, Fast ion conductor, Ionic conductivity, Lithium
Abstract

A nanopowder consisting of La2Zr2O7 particles with lithium containing species on their surface was prepared by spray flame synthesis and subsequently added to Li7La3Zr2O12 powder obtained by a conventional solid-state reaction. The spray flame synthesis method utilized in this work yields nanoparticles with a small size of approximately 5 nm, which is unprecedented within the scope of oxide-based ionic conductors for solid-state batteries. Remarkably, the addition of nanoparticles for sintering at a relatively low temperature of 1000 °C significantly improved the ionic conductivity by 50 %. In contrast, there was no influence of incorporating nanoparticles on the conductivity at sintering temperatures at or above 1100 °C, which is the typical temperature range applied for conventional sintering of Li7La3Zr2O12. Compared to prior published work with analogous materials, a more than twofold improvement in conductivity was demonstrated while the sintering temperature was decreased by 100 °C.

Published
2022
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43. The role of fluorination during the physicochemical erosion of yttria in fluorine-based etching plasmas

Author

Moritz Kindelmann, Egbert Wessel, Moritz L. Weber, Rahel Buschhaus, M. Bram, Olivier Guillon, and Mark Stamminger

Subjects
Materials science, Morphology (linguistics), Composite number, chemistry.chemical_element, Plasma, chemistry, Chemical engineering, Etching (microfabrication), visual_art, ddc:660, Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium, Fluorine, Ceramic, Crystallite, Yttria-stabilized zirconia
Abstract

A physicochemical mechanism acting between the reactive plasma and the material surface controls the erosion of polycrystalline ceramics in fluorine containing etching plasmas. In this study, a Y2O3/YOF composite was exposed to a fluorine etching plasma. Relocalization enables the direct correlation of crystalline orientation with material response. Our study reveals an orientation dependent surface fluorination of Y2O3, which controls the etching resistance and morphology formation. Orientations near the low index planes (001), (010) and (100) exhibit the lowest stability due to a homogeneous surface reaction. The presented results help to extend the mechanistic understanding of the plasma-material interaction of Y2O3.

Published
2022
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44. Technological Pathways to Produce Compressed and Highly Pure Hydrogen from Solar Power

Author

Mariya E. Ivanova, Ralf Peters, Martin Müller, Stefan Haas, Martin Florian Seidler, Gerd Mutschke, Kerstin Eckert, Philipp Röse, Sonya Calnan, Rory Bagacki, Rutger Schlatmann, Cedric Grosselindemann, Laura‐Alena Schäfer, Norbert H. Menzler, André Weber, Roel van de Krol, Feng Liang, Fatwa F. Abdi, Stefan Brendelberger, Nicole Neumann, Johannes Grobbel, Martin Roeb, Christian Sattler, Ines Duran, Benjamin Dietrich, M. E. Christoph Hofberger, Leonid Stoppel, Neele Uhlenbruck, Thomas Wetzel, David Rauner, Ante Hecimovic, Ursel Fantz, Nadiia Kulyk, Jens Harting, and Olivier Guillon

Subjects
Chemical engineering, ddc:540, ddc:660, green hydrogen, General Chemistry, Catalysis
Abstract

Angewandte Chemie / International edition e202218850 (2023). doi:10.1002/anie.202218850 special issue: "Hot Topic: Water Splitting", Published by Wiley-VCH, Weinheim

Published
2023
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46. Enhanced metal exsolution at the non-polar (001) surfaces of multi-faceted epitaxial thin films

Author

Moritz L Weber, Moritz Kindelmann, Egbert Wessel, Alexandros Sarantopoulos, Norbert H Menzler, Regina Dittmann, Rainer Waser, Olivier Guillon, Christian Lenser, and Felix Gunkel

Subjects
General Energy, Materials Science (miscellaneous), Materials Chemistry, ddc:530
Abstract

JPhys energy 5(1), 014002 (2023). doi:10.1088/2515-7655/ac9dbf, Published by IOP Publishing, Bristol

Published
2023
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47. Enabling metal substrates for garnet-based composite cathodes by laser sintering

Author

Walter Sebastian Scheld, Linda Charlotte Hoff, Christian Vedder, Jochen Stollenwerk, Daniel Grüner, Melanie Rosen, Sandra Lobe, Martin Ihrig, Ah–Ram Seok, Martin Finsterbusch, Sven Uhlenbruck, Olivier Guillon, and Dina Fattakhova–Rohlfing

Subjects
General Energy, Mechanical Engineering, Building and Construction, Management, Monitoring, Policy and Law, Elektrotechnik
Published
2023

48. Modelling of elimination of strength-limiting defects by pressure-assisted sintering at low stress levels

Author

Robert Mücke, Olivier Guillon, Gaku Okuma, and Fumihiro Wakai

Subjects
Stress (mechanics), Materials science, Hot isostatic pressing, Void (composites), ddc:660, Materials Chemistry, Ceramics and Composites, Spark plasma sintering, Sintering, Composite material, Hot pressing, Forging, Shrinkage
Abstract

The structural reliability of sintered products depends on large defects introduced during powder processing, which cannot be removed by pressureless sintering. Here, we present a model how a large single ellipsoidal void is deformed, and finally disappears by pressure-assisted sintering. Taya-Seidel’s model is applied to predict the shrinkage of a large void in a compressible linear viscous material by using bulk viscosity, shear viscosity, and sintering stress that are determined experimentally for sintering of alumina powder at low stress levels. The application of mechanical stress promotes the densification rate. Its effect is maximum for hot isostatic pressing (HIP) and minimum for sinter forging. The effect is intermediate for hot pressing (HP) and spark plasma sintering (SPS), because the hydrostatic component of stress varies with densification. While a crack-like defect can be removed during densification, a spherical void must be eliminated by shear deformation in the final stage during dwell time.

Published
2021
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49. The influence of hafnium impurities on the electrochemical performance of tantalum substituted Li7La3Zr2O12 solid electrolytes

Author

Michael Küpers, Olivier Guillon, Martin Finsterbusch, Grit Häuschen, Dina Fattakhova-Rohlfing, and Markus Mann

Subjects
Zirconium, Materials science, Dopant, General Chemical Engineering, Inorganic chemistry, General Engineering, Tantalum, General Physics and Astronomy, chemistry.chemical_element, Conductivity, Hafnium, chemistry, Impurity, Fast ion conductor, Ionic conductivity, ddc:530, General Materials Science
Abstract

Garnet-based Li7La3Zr2O12 (LLZO) is considered one of the most promising oxide-ceramic solid electrolyte materials for inorganic all-solid-state batteries. Dopants and substituents like Al, Ta, Nb, Ga, and W were shown to have a high impact on the total ionic conductivity, increasing it from 10−6 S/cm up to 10−3 S/cm. However, natural zirconium sources always contain a small amount of hafnium which could also act as dopant, but the separation of these two elements is complicated and expensive. In this work, we investigate the influence of various Hf-impurity concentrations on the performance of tantalum-doped LLZO. We synthesised Li6.45Al0.05La3Zr1.6−xHfxTa0.4O12 (LLZHO with x = 0 – 1.6) via conventional solid-state synthesis and have demonstrated that up to x = 0.1, hafnium impurities do not have a significant impact on the performance of the material. Above this concentration, the Li-ion conductivity is steadily reduced to around 70% when zirconium is fully substituted by hafnium resulting in Li6.45Al0.05La3Hf1.6Ta0.4O12. As the purity of Zr precursors has a great impact on their price, these findings can help to reduce the price of LLZO in general, as lower grade zirconium can be used in industrial scale applications.

Published
2021
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50. Residual stress and mechanical strength of Ce0.8Gd0.2O2--FeCo2O4 dual phase oxygen transport membranes

Author

Wilhelm A. Meulenberg, Fanlin Zeng, Arian Nijmeijer, Jürgen Malzbender, Louis Winnubst, Olivier Guillon, Stefan Baumann, and Ruth Schwaiger

Subjects
010302 applied physics, Materials science, Spinel, Oxygen transport, chemistry.chemical_element, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Residual, 01 natural sciences, Dwell time, Membrane, chemistry, Residual stress, Phase (matter), 0103 physical sciences, ddc:660, Materials Chemistry, Ceramics and Composites, engineering, Composite material, 0210 nano-technology, Cobalt
Abstract

Ce0.8Gd0.2O2-δ-FeCo2O4 membranes, benefiting from their excellent chemical stability, exhibit a broad application potential in oxygen-consuming industrial processes running in harsh environments. For long-term reliable operation, the membrane needs to possess sufficient mechanical strength. This paper characterizes the typical aspects that challenge the mechanical stability of the sintered membrane, including composition and microstructural defects as well as residual stress and residual stress gradients. It is revealed that mechanical strengths of the sintered membranes increase with decreasing iron cobalt spinel content, that the high iron cobalt spinel content induces microcracks, and that high residual tensile stress gradually decreases from the as-sintered surface to the bulk. Although the residual tensile stress can be reduced by applying an extensive elevated temperature dwell time during cooling, it is suggested to limit the iron cobalt spinel content to a nominal value of 15 wt% to eliminate the residual tensile stress while maintaining a high mechanical strength.

Published
2021
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