Oxygen Lattice Instability as a Capacity Fading Mechanism for 5 V Cathode Materials

Caballero, Álvaro; Hernán, L.; Melero, M.; Morales, J.; Angulo, Manuel

doi:10.1149/1.1824037

Cited by 29 publications

(19 citation statements)

References 30 publications

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“…They attributed these redox peaks at about 4.9 V vs. Li/Li + to decomposition of the electrolyte. Caballero et al observed an oxidation peak at about 5.1 V and ascribed this peak to the release of oxygen from the spinel framework [72]. According to previous studies [9,17,24,73], the features of the obtained cyclic voltammogram indicates that the as-prepared LNMO exhibited dominantly the disordered structure, which is in accordance to the SAED result.…”

Section: Resultssupporting

confidence: 83%

Electrochemical and Electronic Charge Transport Properties of Ni-Doped LiMn2O4 Spinel Obtained from Polyol-Mediated Synthesis

et al. 2018

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LiNi0.5Mn1.5O4 (LNMO) spinel has been extensively investigated as one of the most promising high-voltage cathode candidates for lithium-ion batteries. The electrochemical performance of LNMO, especially its rate performance, seems to be governed by its crystallographic structure, which is strongly influenced by the preparation methods. Conventionally, LNMO materials are prepared via solid-state reactions, which typically lead to microscaled particles with only limited control over the particle size and morphology. In this work, we prepared Ni-doped LiMn2O4 (LMO) spinel via the polyol method. The cycling stability and rate capability of the synthesized material are found to be comparable to the ones reported in literature. Furthermore, its electronic charge transport properties were investigated by local electrical transport measurements on individual particles by means of a nanorobotics setup in a scanning electron microscope, as well as by performing DFT calculations. We found that the scarcity of Mn3+ in the LNMO leads to a significant decrease in electronic conductivity as compared to undoped LMO, which had no obvious effect on the rate capability of the two materials. Our results suggest that the rate capability of LNMO and LMO materials is not limited by the electronic conductivity of the fully lithiated materials.

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Section: Resultssupporting

confidence: 83%

Electrochemical and Electronic Charge Transport Properties of Ni-Doped LiMn2O4 Spinel Obtained from Polyol-Mediated Synthesis

et al. 2018

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“…The presence of impurities such as traces of organic components seems to play a minor role here. The unresolved peak above 4.8 V, which was specially significant for the PEG 400 sample but barely visible for the PEG 800 sample, can be assigned to either electrolyte oxidation [40] or release of oxygen from the spinel lattice. [41] The electrochemical performance of the two spinels was assessed from galvanostatic measurements made over a wide range of charge/discharge rates (from C/4 to 15C, where C represents 1 Li + ion exchanged in 1 h equivalent to 148 mA g -1 ) and cycling over the voltage range 3.5-5.0 V. Figure 7 shows the variation of the discharge capacity of the two spinels obtained from the PEG-based synthesis recorded at two rates, C/4 and 4C, as a function of cycle number.…”

Section: Full Papermentioning

confidence: 97%

“…The coulombic efficiency of the electrode made from the spinel obtained in the absence of PEG is also included for comparison. The first four cycles were excluded owing to the overcharge introduced by the charging process as the potential result of some oxygen being released above 4.8 V [40] and/or electrolyte oxidation. [41] Although most values exceeded 95 %-which suggests good coulombic efficiency of both electrodes-there were small differences that are worth some comment.…”

Section: Full Papermentioning

confidence: 99%

Crystallinity Control of a Nanostructured LiNi_0.5Mn_1.5O₄ Spinel via Polymer‐Assisted Synthesis: A Method for Improving Its Rate Capability and Performance in 5 V Lithium Batteries

Arrebola

Caballero

Cruz

et al. 2006

Adv Funct Materials

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128

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Li–Ni–Mn spinels of nominal composition LiNi0.5Mn1.5O4, which are functional materials for electrodes in high‐voltage lithium batteries, are prepared by thermal decomposition of mixed nanocrystalline oxalates obtained by grinding hydrated salts and oxalic acid in the presence of polyethyleneglycol 400. Their structure, microstructure, and texture are established from combined X‐ray photoelectron spectroscopy (XPS), X‐ray diffraction, transmission electron microscopy (TEM), IR spectroscopy, and N2 absorption measurements. The polymer tailors the shape of particles, which adopt a nanorodlike morphology at low temperatures (400 °C). In fact, the nanorods consist of highly distorted oriented nanocrystals connected by a polymer‐based film as inferred from IR and XPS spectra. The electrochemical properties of spinels in this peculiar form are quite poor, mainly as a result of the high microstrain content of their nanocrystals. Raising the temperature up to 800 °C partially destroys the nanorods, which become highly crystalline nanoparticles approximately 80 nm in size. At this temperature, the polymer facilitates crystal growth; this leads to highly crystalline polyhedral nanoparticles as revealed from TEM images and microstrain data. Following functionalization as a cathode in lithium cells, this material exhibits a very good rate capability, coulombic efficiency, and capacity retention even upon cycling at voltages as high as 5 V. Moreover, it withstands fast‐charge–slow‐discharge processes, which is an important cycle‐life‐related property for commercial batteries.

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“…21 The Cu spinels, particularly sample Cu-800, exhibit the most marked differences between experimental and theoretical values. One salient feature is the good consistency between the experimental capacity and the content in Cu 2ϩ at octahedral positions; this suggests that Cu 2ϩ ions at tetrahedral positions are electrochemically inactive below 5.0 V regardless of their origin.…”

Section: Resultsmentioning

confidence: 97%

Oxygen Deficiency as the Origin of the Disparate Behavior of LiM[sub 0.5]Mn[sub 1.5]O[sub 4] (M = Ni, Cu) Nanospinels in Lithium Cells

Caballero

Cruz

Hernán

et al. 2005

J. Electrochem. Soc.

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A comparative study of the electrochemical properties of two spinels of nominal composition LiM 0.5 Mn 1.5 O 4 ͑M ϭ Ni, Cu͒ was conducted. The doping element introduces significant structural changes in stoichiometry, cation distribution, and oxidation state of the elements. Whereas Ni spinels were virtually stoichiometric and exhibit mostly normal structure, the Cu samples were oxygen-deficient spinels with a greater contribution of the inverse structure. This was especially so in the sample obtained at 800°C, where X-ray photoelectron spectroscopy ͑XPS͒ revealed the presence of Cu ϩ . Its electron configuration favored the occupancy of tetrahedral positions and the resulting displacement of some Li ϩ ions to octahedral positions. All these features account for the increased Mn 3ϩ content of the Cu spinels, consistent with electrochemical measurements. Ex situ XPS measurements confirmed the oxidation processes of Ni and Cu ions on charging the cell at 5.0 V, and the reversibility of the electrochemical reaction undergone by Ni. However, the reversibility of the Cu 2ϩ Cu 3ϩ reaction could not be demonstrated because of the low capacity delivered by the cell in the 5.0-4.5 V region. The structural defects in the Cu spinels have an adverse impact on cell performance. Compared to the Ni spinel, the Cu spinel possesses a low discharge capacity that fades faster on cycling.The partial substitution of some manganese in LiMn 2 O 4 by various transition metals is known to endow it with the ability to deliver a substantial capacity at voltages above 4.5 V. 1-3 Ni-doped spinels have received much attention on account of their improved cycling behavior relative to the undoped spinel. 4-11 Thus, a highly pure LiNi 0.5 Mn 1.5 O 4 phase exhibits a flat operating voltage of ca. 4.7 V and an initial discharge capacity of 139 mAh/g, which is more than 90% of the theoretical capacity based on the Ni 2ϩ /Ni 4ϩ redox couple. 10,11 The origin of the difference between the theoretical and real capacity may be slight deviations from the previous composition resulting in the presence of Mn 3ϩ and the content which depends on the particular synthetic conditions. To the authors' knowledge, Cu-doped spinels have received comparatively little attention. Only several papers by the same research group have so far dealt with the electrochemical properties of LiCu 0.5 Mn 1.5 O 4 in lithium cells. [12][13][14][15] The copper spinel exhibits at least two significant differences relative to LiNi 0.5 Mn 1.5 O 4 , namely, ͑i͒ the capacity corresponding to the high-potential plateau is only 24 mAh/g ͑i.e., much lower than that calculated for the Cu 2ϩ → Cu 3ϩ process͒ and (ii) substantial capacity in the 3.5-4.5 V region ͑48 mAh/g͒ resulting from the Mn 3ϩ /Mn 4ϩ redox couple despite the formal absence of Mn 3ϩ from the spinel formula. Other possibilities such as the involvement of alternative oxidation states of Cu ͑particularly Cu ϩ or Cu 3ϩ ) require confirmation. 12 The aim of this paper is to facilitate understanding of the peculiar electrochemi...

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Oxygen Lattice Instability as a Capacity Fading Mechanism for 5 V Cathode Materials

Cited by 29 publications

References 30 publications

Electrochemical and Electronic Charge Transport Properties of Ni-Doped LiMn2O4 Spinel Obtained from Polyol-Mediated Synthesis

Electrochemical and Electronic Charge Transport Properties of Ni-Doped LiMn2O4 Spinel Obtained from Polyol-Mediated Synthesis

Crystallinity Control of a Nanostructured LiNi_0.5Mn_1.5O₄ Spinel via Polymer‐Assisted Synthesis: A Method for Improving Its Rate Capability and Performance in 5 V Lithium Batteries

Oxygen Deficiency as the Origin of the Disparate Behavior of LiM[sub 0.5]Mn[sub 1.5]O[sub 4] (M = Ni, Cu) Nanospinels in Lithium Cells

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Oxygen Lattice Instability as a Capacity Fading Mechanism for 5 V Cathode Materials

Cited by 29 publications

References 30 publications

Electrochemical and Electronic Charge Transport Properties of Ni-Doped LiMn2O4 Spinel Obtained from Polyol-Mediated Synthesis

Electrochemical and Electronic Charge Transport Properties of Ni-Doped LiMn2O4 Spinel Obtained from Polyol-Mediated Synthesis

Crystallinity Control of a Nanostructured LiNi0.5Mn1.5O4 Spinel via Polymer‐Assisted Synthesis: A Method for Improving Its Rate Capability and Performance in 5 V Lithium Batteries

Oxygen Deficiency as the Origin of the Disparate Behavior of LiM[sub 0.5]Mn[sub 1.5]O[sub 4] (M = Ni, Cu) Nanospinels in Lithium Cells

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Crystallinity Control of a Nanostructured LiNi_0.5Mn_1.5O₄ Spinel via Polymer‐Assisted Synthesis: A Method for Improving Its Rate Capability and Performance in 5 V Lithium Batteries