Single step synthesis of W-modified LiNiO<sub>2</sub> using an ammonium tungstate flux

Goonetilleke, Damian; Mazilkin, Andrey; Weber, Daniel; Ma, Yuan; Fauth, François; Janek, Jürgen; Brezesinski, Torsten; Bianchini, Matteo

doi:10.1039/d1ta10568j

“…Coatings of high-valence metal compounds have been explored in Ni-rich materials, including those with W, Ti, Ta, Sb, Nb, etc. − Tungsten addition has been reported previously to improve the performance and recently published work shows that W does not substitute into the TM layer but rather stays in the grain boundaries in the form of Li x W y O z secondary phases. − This behavior is not unique to W. Mo, Nb, and Sb are also observed to be enriched at grain boundaries. , The formation of secondary phases in the grain boundaries can potentially act as a barrier to prevent interdiffusion of transition metals during synthesis, therefore, making it possible to synthesize core–shell and other microstructures even with elements like Mg and Al which ordinarily diffuse rapidly. Stable thin shells may also be possible to produce without compromising the optimum synthesis temperature.…”

mentioning

confidence: 99%

Preventing Interdiffusion during Synthesis of Ni-Rich Core–Shell Cathode Materials

Rathore

¹

,

Garayt

²

,

Liu

³

et al. 2022

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Surface reactions between Ni-rich cathode materials and electrolytes limit the achievable specific capacity and lifetime in the high energy density Li-ion batteries based on these cathode materials. A core−shell approach, which contains a less reactive shell-phase on top of a high-capacity core-phase, can be used to reduce these surface reactions. However, interdiffusion of the elements in the core and shell phases can occur during calcination, which limits the choice of elements to be used in the shell phase and the temperature window of synthesis, and often increases the minimum shell thickness. Tungsten oxide (WO 3 ) coating on the surface of precursors leads to the formation of Li x W y O z secondary phases during the heat treatment with LiOH• H 2 O. These Li x W y O z phases infuse into the grain boundaries and prevent interdiffusion between the core and shell phases. Tungsten-containing Ni-rich core−shell cathode materials with Mn-or Al-based shells show enhanced electrochemical performance because of reduced surface reactivity due to the core−shell microstructure and additional mechanical strength owing to the presence of Li x W y O z phases in the grain boundaries.

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“…1b) of pristine WLNO can be fit with a rhombohedral R3 ̅ m unit cell with the refined lattice parameters comparable to those in literature (Table S1). [47,49,50] No traces of unreacted precursors are seen. However, there is compelling evidence that true bulk W doping (i.e., W occupying Li and/or Ni sites) does not occur in WLNO, and that amorphous LixWyOz phases are formed along grain boundaries and particle surfaces.…”

Section: Pristine Materials and Electrochemistrymentioning

confidence: 98%

Oxygen-redox activity in non-Li-excess W-doped LiNiO2 cathode

Menon

¹

,

Johnston

²

,

Booth

³

et al. 2023

Preprint

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The desire to increase the energy density of stoichiometric layered LiTMO2 (TM = 3d transition metal) cathode materials has promoted investigation into their properties at high states of charge. Although there is increasing evidence for pronounced oxygen participation in the charge compensation mechanism, questions remain whether this is true O-redox, as observed in Li-excess cathodes. Through a high-resolution O K-edge resonant inelastic X-ray spectroscopy (RIXS) study of the Mn-free Ni-rich layered oxide, LiNi0.98W0.02O2, we demonstrate that the same oxidized oxygen environment exists in both Li-excess and non-Li-excess systems. The observation of identical RIXS loss features in both classes of compounds is remarkable given the differences in their crystallographic structure and delithiation pathways. This lack of a specific structural motif reveals the importance of electron correlation in the charge compensation mechanism for these systems and indicates how a better description of charge compensation in layered oxides is required to understand anionic redox for energy storage.

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“…1b) of pristine WLNO can be fit with a rhombohedral R3 ̅ m unit cell with the refined lattice parameters comparable to those in literature (Table S1). [33,35,36] No traces of unreacted precursor are seen. However, there is compelling evidence that true bulk W doping (i.e., W occupying Li/Ni sites) does not occur in WLNO, and that amorphous LixWyOz (x/y > 1) phases are formed along grain boundaries and particle surfaces.…”

Section: Pristine Materials and Electrochemistrymentioning

confidence: 99%

“…These values are lower than those previously reported for comparable W-doped LiNiO2 samples (~5%). [33,35,36] This is most likely a consequence of the solid-state doping approach, which can impart a higher degree of heterogeneity in the W doping due to its inherent sluggish kinetics. [43] Taken together, the refinements provide strong evidence that the WLNO exhibits some offstoichiometry with an appreciable amount of Ni present in the Li layer.…”

Section: Pristine Materials and Electrochemistrymentioning

confidence: 99%

“…To probe the nature of oxidized O 2− species in non-Li-excess cathodes, we performed an O K-edge hr-RIXS study using 2% tungsten doped LiNiO2 (LiNi0.98W0.02O2) as a model system. In addition to its superior electrochemical performance compared to undoped LiNiO2 [33][34][35][36], it is a Mn-free system, which removes the possibility of the theoretically predicted [37] but experimentally unverified [38,39] Mn 4+ to Mn 7+ oxidation and the stabilization of orphaned O 2p orbitals by Mn. [40][41][42] The crystallographic and electronic structure changes in the LiNi0.98W0.02O2 cathode were investigated as a function of delithiation using X-ray diffraction and spectroscopy methods.…”

Section: Introductionmentioning

confidence: 99%

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Oxygen-redox activity in non-Li-excess W-doped LiNiO2 cathode

Menon

¹

,

Johnston

²

,

Booth

³

et al. 2022

Preprint

1

0

View full text Add to dashboard Cite

The desire to increase the energy density of stoichiometric layered LiTMO2 (TM = 3d transition metal) cathode materials has promoted investigation into their properties at high states of charge. Although there is increasing evidence for pronounced oxygen participation in the charge compensation mechanism, questions remain whether this is true O-redox, as observed in Li-excess cathodes. Through a high-resolution O K-edge resonant inelastic X-ray spectroscopy (RIXS) study of the Mn-free Ni-rich layered oxide, LiNi0.98W0.02O2, we demonstrate that the same oxidized oxygen environment exists in both Li-excess and non-Li-excess systems. The observation of identical RIXS loss features in both classes of compounds is remarkable given the differences in their crystallographic structure and delithiation pathways. This lack of a specific structural motif reveals the importance of electron correlation in the charge compensation mechanism for these systems and indicates how a better description of charge compensation in layered oxides is required to understand anionic redox for energy storage.

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Single step synthesis of W-modified LiNiO₂ using an ammonium tungstate flux

Abstract: Modification of LiNiO2 with small amounts of W in a simple one-step synthesis process leads to changes in the crystal structure and electrochemical behavior, but it is also consequential for physical features such as the materials' morphology and thermal stability.

Cited by 27 publications

References 91 publications

Preventing Interdiffusion during Synthesis of Ni-Rich Core–Shell Cathode Materials

Preventing Interdiffusion during Synthesis of Ni-Rich Core–Shell Cathode Materials

Oxygen-redox activity in non-Li-excess W-doped LiNiO2 cathode

Oxygen-redox activity in non-Li-excess W-doped LiNiO2 cathode

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Single step synthesis of W-modified LiNiO2 using an ammonium tungstate flux

Abstract: Modification of LiNiO2 with small amounts of W in a simple one-step synthesis process leads to changes in the crystal structure and electrochemical behavior, but it is also consequential for physical features such as the materials' morphology and thermal stability.

Cited by 27 publications

References 91 publications

Preventing Interdiffusion during Synthesis of Ni-Rich Core–Shell Cathode Materials

Preventing Interdiffusion during Synthesis of Ni-Rich Core–Shell Cathode Materials

Oxygen-redox activity in non-Li-excess W-doped LiNiO2 cathode

Oxygen-redox activity in non-Li-excess W-doped LiNiO2 cathode

Contact Info

Product

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Single step synthesis of W-modified LiNiO₂ using an ammonium tungstate flux