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Main Authors: Lourens, Florian, Suhr, Ellen, Schnickmann, Alena, Schirmer, Thomas, Ludwig, Alfred
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.04146
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author Lourens, Florian
Suhr, Ellen
Schnickmann, Alena
Schirmer, Thomas
Ludwig, Alfred
author_facet Lourens, Florian
Suhr, Ellen
Schnickmann, Alena
Schirmer, Thomas
Ludwig, Alfred
contents The increasing importance of recycling makes the recovery of valuable elements from slags interesting, e.g., by the concept of engineered artificial minerals (EnAMs). In this concept, it is aimed for the formation of EnAMs, meaning phase(s) with a high content of the to-be-recovered element(s) from slags of pyrometallurgical recycling processes. For this, understanding the phase constitution of the slag systems is of high importance. The system Mg-Mn-Al-O is a metal oxide slag subsystem from Li-ion battery recycling, that is critical for the formation of spinel phases, which are competing phases to the possible Li-containing EnAM phase LiAlO2. Here, the phase constitution was investigated using a thin film materials library that covers the composition space (Mg14-69Mn11-38Al14-74)Ox. By means of high-throughput energy-dispersive X-ray spectroscopy and X-ray diffraction, the formation of the spinel solid solution phase was confirmed for a wide composition space. Increasing preferential orientation of the spinel solid solution along (400) with increasing Mg content was identified. X-ray photoelectron spectroscopy was used to measure the near-surface composition of selected areas of the materials library, and detailed peak fitting of the Mn 2p3/2 region revealed the Mn oxidation state to be a mixture of Mn2+ and Mn3+. For one measurement area of the materials library containing equal atomic amounts of Mg, Mn and Al, transmission electron microscopy showed that the approximately 420 nm-thick film consists of columnar spinel grains with Mg, Mn and Al being evenly distributed. Based on these results, we suggest that the shown high likelihood of spinel formation in slags might be influenced by controlling the Mn oxidation state to enable the formation of desirable EnAM phases.
format Preprint
id arxiv_https___arxiv_org_abs_2312_04146
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle High-throughput study of the phase constitution of the thin film system Mg-Mn-Al-O in relation to Li recovery from slags
Lourens, Florian
Suhr, Ellen
Schnickmann, Alena
Schirmer, Thomas
Ludwig, Alfred
Materials Science
The increasing importance of recycling makes the recovery of valuable elements from slags interesting, e.g., by the concept of engineered artificial minerals (EnAMs). In this concept, it is aimed for the formation of EnAMs, meaning phase(s) with a high content of the to-be-recovered element(s) from slags of pyrometallurgical recycling processes. For this, understanding the phase constitution of the slag systems is of high importance. The system Mg-Mn-Al-O is a metal oxide slag subsystem from Li-ion battery recycling, that is critical for the formation of spinel phases, which are competing phases to the possible Li-containing EnAM phase LiAlO2. Here, the phase constitution was investigated using a thin film materials library that covers the composition space (Mg14-69Mn11-38Al14-74)Ox. By means of high-throughput energy-dispersive X-ray spectroscopy and X-ray diffraction, the formation of the spinel solid solution phase was confirmed for a wide composition space. Increasing preferential orientation of the spinel solid solution along (400) with increasing Mg content was identified. X-ray photoelectron spectroscopy was used to measure the near-surface composition of selected areas of the materials library, and detailed peak fitting of the Mn 2p3/2 region revealed the Mn oxidation state to be a mixture of Mn2+ and Mn3+. For one measurement area of the materials library containing equal atomic amounts of Mg, Mn and Al, transmission electron microscopy showed that the approximately 420 nm-thick film consists of columnar spinel grains with Mg, Mn and Al being evenly distributed. Based on these results, we suggest that the shown high likelihood of spinel formation in slags might be influenced by controlling the Mn oxidation state to enable the formation of desirable EnAM phases.
title High-throughput study of the phase constitution of the thin film system Mg-Mn-Al-O in relation to Li recovery from slags
topic Materials Science
url https://arxiv.org/abs/2312.04146