Falk Meutzner scite author profile

The expansion of renewable energy and the growing number of electric vehicles and mobile devices are demanding improved and low-cost electrochemical energy storage. In order to meet the future needs for energy storage, novel material systems with high energy densities, readily available raw materials, and safety are required. Currently, lithium and lead mainly dominate the battery market, but apart from cobalt and phosphorous, lithium may show substantial supply challenges prospectively, as well. Therefore, the search for new chemistries will become increasingly important in the future, to diversify battery technologies. But which materials seem promising? Using a selection algorithm for the evaluation of suitable materials, the concept of a rechargeable, high-valent all-solid-state aluminum-ion battery appears promising, in which metallic aluminum is used as the negative electrode. On the one hand, this offers the advantage of a volumetric capacity four times higher (theoretically) compared to lithium analog. On the other hand, aluminum is the most abundant metal in the earth's crust. There is a mature industry and recycling infrastructure, making aluminum very cost efficient. This would make the aluminum-ion battery an important contribution to the energy transition process, which has already started globally. So far, it has not been possible to exploit this technological potential, as suitable positive electrodes and electrolyte materials are still lacking. The discovery of inorganic materials with high aluminum-ion mobility—usable as solid electrolytes or intercalation electrodes—is an innovative and required leap forward in the field of rechargeable high-valent ion batteries. In this review article, the constraints for a sustainable and seminal battery chemistry are described, and we present an assessment of the chemical elements in terms of negative electrodes, comprehensively motivate utilizing aluminum, categorize the aluminum battery field, critically review the existing positive electrodes and solid electrolytes, present a promising path for the accelerated development of novel materials and address problems of scientific communication in this field.

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Printing Nearly-Discrete Magnetic Patterns Using Chemical Disorder Induced Ferromagnetism

Bali

et al. 2014

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Ferromagnetism in certain alloys consisting of magnetic and nonmagnetic species can be activated by the presence of chemical disorder. This phenomenon is linked to an increase in the number of nearest-neighbor magnetic atoms and local variations in the electronic band structure due to the existence of disorder sites. An approach to induce disorder is through exposure of the chemically ordered alloy to energetic ions; collision cascades formed by the ions knock atoms from their ordered sites and the concomitant vacancies are filled randomly via thermal diffusion of atoms at room temperature. The ordered structure thereby undergoes a transition into a metastable solid solution. Here we demonstrate the patterning of highly resolved magnetic structures by taking advantage of the large increase in the saturation magnetization of Fe60Al40 alloy triggered by subtle atomic displacements. The sigmoidal characteristic and sensitive dependence of the induced magnetization on the atomic displacements manifests a sub-50 nm patterning resolution. Patterning of magnetic regions in the form of stripes separated by ∼ 40 nm wide spacers was performed, wherein the magnet/spacer/magnet structure exhibits reprogrammable parallel (↑/spacer/↑) and antiparallel (↑/spacer/↓) magnetization configurations in zero field. Materials in which the magnetic behavior can be tuned via ion-induced phase transitions may allow the fabrication of novel spin-transport and memory devices using existing lateral patterning tools.

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Combined Theoretical Approach for Identifying Battery Materials: Al³⁺ Mobility in Oxides

et al. 2019

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In this work, we take a significant step forward in the Al-ion battery material search by screening already existing aluminum compounds not considered in this regard before. A novel combination of different established theoretical methods to filter structural databases is applied here. The presented highthroughput analysis minimizes the computational time, while still providing reliable results. Starting with Voronoi−Dirichlet partitioning of 4346 aluminum oxides listed in the Inorganic Crystal Structure Database, bond valence and density functional theory calculations are subsequently performed. AlVO 3 is the most promising candidate for the cathode materials found. Limitations of the filter are discussed, with emphasis being placed on the comparison of the data derived from the different methods. The broad coincidence of the found migration networks and the trend in migration barriers validate the screening algorithm. In further studies, the filter can be applied to rapidly find crystalline electrolytes and electrodes for other mobile species as well.

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Falk Meutzner

The Aluminum-Ion Battery: A Sustainable and Seminal Concept?

Printing Nearly-Discrete Magnetic Patterns Using Chemical Disorder Induced Ferromagnetism

Combined Theoretical Approach for Identifying Battery Materials: Al³⁺ Mobility in Oxides

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Falk Meutzner

The Aluminum-Ion Battery: A Sustainable and Seminal Concept?

Printing Nearly-Discrete Magnetic Patterns Using Chemical Disorder Induced Ferromagnetism

Combined Theoretical Approach for Identifying Battery Materials: Al3+ Mobility in Oxides

Contact Info

Product

Resources

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Combined Theoretical Approach for Identifying Battery Materials: Al³⁺ Mobility in Oxides