<?xml version='1.0' encoding='UTF-8'?><metadata xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:dc="http://purl.org/dc/elements/1.1/" xmlns:dcterms="http://purl.org/dc/terms/" xmlns="http://dublincore.org/documents/dcmi-terms/"><dcterms:title>Replication Data for: Tailoring Li-Al-O Interphases in Garnet-Type Solid-State Electrolytes via Powder Atomic Layer Deposition</dcterms:title><dcterms:identifier>https://doi.org/10.26165/JUELICH-DATA/1XFQBW</dcterms:identifier><dcterms:creator>Steinhoff, Michael</dcterms:creator><dcterms:creator>Domgans, Anna</dcterms:creator><dcterms:creator>Ahmed, Jehad</dcterms:creator><dcterms:creator>Schierholz, Roland</dcterms:creator><dcterms:creator>Daniel, Davis Thomas</dcterms:creator><dcterms:creator>Aghdassi, Nabi</dcterms:creator><dcterms:creator>Yu, Shicheng</dcterms:creator><dcterms:creator>Tempel, Hermann</dcterms:creator><dcterms:creator>Eichel, Rüdiger-A.</dcterms:creator><dcterms:publisher>Jülich DATA</dcterms:publisher><dcterms:issued>2026-03-09</dcterms:issued><dcterms:modified>2026-03-09T09:29:17Z</dcterms:modified><dcterms:description>&lt;h2>Study Overview&lt;/h2>&#xd;
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In this study, the influence of atomic layer deposition (ALD) derived Li-Al-O interphases in garnet-type Li&lt;sub>6.4&lt;/sub>La&lt;sub>3&lt;/sub>Zr&lt;sub>1.4&lt;/sub>Ta&lt;sub>0.6&lt;/sub>O&lt;sub>12&lt;/sub> (LLZTO) solid-state electrolyte (SSE) was investigated. Garnet-type SSE are prone to lithium dendrite growth along interfaces, which causes short-circuits, significantly reducing cell performance. ALD offers high control over coating chemistry and morphology to precisly modify these interfaces in SSEs. Here, Al&lt;sub>2&lt;/sub>O&lt;sub>3&lt;/sub> ALD coatings were applied on LLZTO powder. MAS NMR, XPS and STEM analysis reveal the formation of a compositionally graded Li-Al-O interphase upon deposition due to proton-exchange-induced lithium diffusion. During high-temperature sintering, the ALD coating induces densification and considerable interdiffusion with LLZTO, resulting in a multi-phase microstructure which can be directly controlled via the ALD process, as confirmed by XRD, SEM and EDS measurments. Electrochemical testing reveals that medium-thickness coatings (~ 6.8 nm,  25 ALD cycles) yield optimal performance, exhibiting ionic conductivity at room temperature of 0.39 mS/cm with good Li-dendrite resitance and long-term cycling stability.&#xd;
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&lt;h2>Dataset Description&lt;/h2>&#xd;
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This dataset contains NMR, XPS, XRD, Ellipsometry, EDS line scans, and electrochemical measurements to investigate Li-Al-O interphases in LLZTO.&#xd;
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The dataset is organized into the following folders:&#xd;
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&lt;dt>&lt;strong>NMR&lt;/strong>&lt;/dt>&#xd;
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&lt;sup>27&lt;/sup>Al Solid-state magic angle spinning nuclear magnetic resonance (MAS NMR) spectroscopy experiments were performed using an AvanceNEO spectrometer (Bruker). Data are stored in the folder &lt;code>NMR&lt;/code>.&#xd;
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&lt;dt>&lt;strong>XPS&lt;/strong>&lt;/dt>&#xd;
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X-ray photoelectron spectroscopy (XPS) measurements of the Al 2p and C 1s region were conducted using a NEXSA G2 spectrometer (Thermo Fisher Scientific). Data are stored in the folder &lt;code>XPS&lt;/code>.&#xd;
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&lt;dt>&lt;strong>XRD&lt;/strong>&lt;/dt>&#xd;
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X-ray diffraction (XRD) experiments were recorded using an Empyrean diffractometer (Pananalytical). Quantitative phase analysis (QPA) on the XRD diffractograms were conducted using the software package Diffrac.Topas version 7 (Bruker). The corresponding diffractograms and fitting data are stored in the folder &lt;code>XRD&lt;/code>.&#xd;
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&lt;dt>&lt;strong>Ellipsometry&lt;/strong>&lt;/dt>&#xd;
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Ellipsometry data were recorded using a FS-8 spectroscopic ellipsometer (Film Sense LLC). Data are stored in the folder &lt;code>Ellipsometry&lt;/code>.&#xd;
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&lt;dt>&lt;strong>Electrochemistry&lt;/strong>&lt;/dt>&#xd;
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Electrochemical impedance spectroscopy (EIS), critical current density (CCD) measurements, long-term plating/stripping experiments and chronoamperometry (CA) measurements were performed. Data are stored in the folder &lt;code>Electrochemistry&lt;/code>.&#xd;
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&lt;dt>&lt;strong>EDS line profile&lt;/strong>&lt;/dt>&#xd;
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EDS line profiles were recorded using a FEI Titan G2 80-200 CREWLEY system. Data are stored in the folder &lt;code>EDS_line_profile&lt;/code>.&#xd;
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&lt;/dl></dcterms:description><dcterms:subject>Chemistry</dcterms:subject><dcterms:contributor>Steinhoff, Michael</dcterms:contributor><dcterms:contributor>Steinhoff, Michael</dcterms:contributor><dcterms:contributor>Domgans, Anna</dcterms:contributor><dcterms:contributor>Ahmed, Jehad</dcterms:contributor><dcterms:contributor>Schierholz, Roland</dcterms:contributor><dcterms:contributor>Daniel, Davis Thomas</dcterms:contributor><dcterms:contributor>Agdhassi, Nabi</dcterms:contributor><dcterms:contributor>Yu, Shicheng</dcterms:contributor><dcterms:contributor>Tempel, Hermann</dcterms:contributor><dcterms:contributor>Eichel, Rüdiger-A.</dcterms:contributor><dcterms:dateSubmitted>2025-09-18</dcterms:dateSubmitted><dcterms:license>CCBY</dcterms:license></metadata>