Passivation Layer and Cathodic Redox Reactions in Sodium‐Ion Batteries Probed by HAXPES

Doubaji, Siham; Philippe, Bertrand; Saadoune, Ismae͏̈l; Gorgoi, Mihaela; Gustafsson, Torbjörn; Solhy, Abderrahim; Valvo, Mario; Rensmo, Håkan; Edström, Kristina

doi:10.1002/cssc.201501282

Cited by 70 publications

(112 citation statements)

References 73 publications

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“…However, the -CF 2 signal is still present, suggesting that the SEI layer is thin, in agreement with the previous results obtained from C 1s and O 1s peaks. Moreover, the intensity of the NaF component slightly increases during Na + extraction in Na 4 Ti 3 O 7 , probably due to the fact that more NaF is formed upon Na + extraction than upon insertion, which would agree with the behavior that is observed in other Na-and Li-based cathode materials [35,36].…”

Section: Study Of the Sei/spi Layers By Conventional Xps Experimentssupporting

confidence: 83%

Influence of Using Metallic Na on the Interfacial and Transport Properties of Na-Ion Batteries

et al. 2017

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Na2Ti3O7 is a promising negative electrode for rechargeable Na-ion batteries; however, its good properties in terms of insertion voltage and specific capacity are hampered by the poor capacity retention reported in the past. The interfacial and ionic/electronic properties are key factors to understanding the electrochemical performance of Na2Ti3O7. Therefore, its study is of utmost importance. In addition, although rather unexplored, the use of metallic Na in half-cell studies is another important issue due to the fact that side-reactions will be induced when metallic Na is in contact with the electrolyte. Hence, in this work the interfacial and transport properties of full Na-ion cells have been investigated and compared with half-cells upon electrochemical cycling by means of X-ray photoelectron spectroscopy (conventional XPS and Auger parameter analysis) and electrochemical impedance spectroscopy. The half-cell has been assembled with C-coated Na2Ti3O7 against metallic Na whilst the full-cell uses C-coated Na2Ti3O7 as negative electrode and NaFePO4 as positive electrode, delivering 112 Wh/kganode+cathode in the 2nd cycle. When comparing both types of cells, it has been found that the interfacial properties, the OCV (open circuit voltage) and the electrode—electrolyte interphase behavior are more stable in the full-cell than in the half-cell. The electronic transition from insulator to conductor previously observed in a half-cell for Na2Ti3O7 has also been detected in the full-cell impedance analysis

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Section: Study Of the Sei/spi Layers By Conventional Xps Experimentssupporting

confidence: 83%

Influence of Using Metallic Na on the Interfacial and Transport Properties of Na-Ion Batteries

et al. 2017

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“…To achieve a reliable assignment, it is inevitable to take additionally the Mn 3s splitting energy as well as the Mn 3p binding energy into account. In the case of the Mn 3s, splitting energies of 4.5, 5.5, and 6.5 eV are, respectively, correlated to Mn 4+ , Mn 3+ , and Mn 2+ ions, and therefore, the splitting of about 5.5 eV shown in Figure b for the Li‐Mn‐O system clearly corroborates the Mn 3+ state . According to the literature, the Mn 3p spectrum was deconvoluted into peaks originating from 5 P and a broad peak from 7 P .…”

Section: Resultsmentioning

confidence: 61%

“…Obviously, the major reason for this fact is mainly due to the complex multiplet splitting, peak overlaps, and additional shake‐up and plasmon features in the respective 2p XP spectra, although fundamental studies are available mainly by the work of Biesinger et al, who considered a semiempirical approach combining the analysis of high purity oxide/hydroxide reference samples and theoretically calculated free‐ion multiplet structures of core 2p vacancy levels by Gupta and Sen . Aside presenting only raw data sets and solely assigning expected oxidation states, simplifying approaches such as reducing the complex multiplet splitting to single Voigt peak shapes are often used, which, in consequence, could lead at least to uncertainties in the quantitative chemical information. To the best of our knowledge, only a few groups apply complex multiplet fitting procedures during XPS characterization of LIB active materials …”

Section: Introductionmentioning

confidence: 99%

Surface analytical approaches to reliably characterize lithium ion battery electrodes

Azmi

Trouillet

Strafela

et al. 2017

Surface & Interface Analysis

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Active Li-ion battery materials are typically characterized using X-ray photoelectron spectroscopy when regarding chemical state elucidation. This work presents a multiplet-splitting approach comprising in minimum 3 third-row transition metals, namely, Mn, Co, and Ni, to improve the results in comparison to peak barycenter or single symmetric Voigt profile approaches. The achieved X-ray photoelectron spectroscopy 2p templates in particular address the complex peak structures consisting of significant photoelectron multiplet splitting, shake-up and plasmon loss features, and additional Auger and photoelectron overlaps, inevitable also for a reliable quantification. To separate from topography effects and contributions of the electrode's binder and conductive carbon in powder electrodes, the developed procedure in a first attempt was successfully transferred to novel radio frequency magnetron sputtered Li-Ni-Co-Mn-O thin films, designed for all-solid-state Li-ion batteries. In all cases, special care was taken with respect to air sensitivity, contamination during sample handling, and probable method induced sample decomposition. Composition and origin of the anode's surface electrolyte interphase are rather complicated, and therefore, XPS and time-of-flight secondary ion mass spectrometry results are still controversially discussed. [5][6][7][8][9][10][11] However, in the case of the first-row transition metals, which are commonly used in LIB's cathodes, the analytical potential of XPS is not widely used in its entirety. Obviously, the major reason for this fact is mainly due to the complex multiplet splitting, peak overlaps, and additional shake-up and plasmon features in the respective 2p XP spectra, although fundamental studies are available mainly by the work of Biesinger et al, 12 who considered a semiempirical approach combining the analysis of high purity oxide/hydroxide reference samples and theoretically calculated free-ion multiplet structures of core 2p vacancy levels by Gupta and Sen. 13 Aside presenting only raw data sets and solely assigning expected oxidation states, [14][15][16][17][18][19][20] simplifying approaches such as reducing the complex multiplet splitting to single Voigt peak shapes are often used, which, in consequence, could lead at least to uncertainties in the quantitative chemical information. 17,[21][22][23][24] To the best of our knowledge, only a few groups apply complex multiplet fitting procedures during XPS characterization of LIB active materials. 25,26

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“…We are confronting two cases, when the charge process is limited to 4.3 V a small and non‐reversible plateau is recognized, but when the voltage is increased to 4.5 V the plateau became partially reversible. Indeed, the electrolyte may decompose at higher voltages and the products, resulting from electrolyte degradation, can react with the electrode surface and can be the main origin of the plateau …”

Section: Resultsmentioning

confidence: 99%

Evidence of a Pseudo‐Capacitive Behavior Combined with an Insertion/Extraction Reaction Upon Cycling of the Positive Electrode Material P2‐Na_xCo_0.9Ti_0.1O₂ for Sodium‐ion Batteries

et al. 2019

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Layered oxides are promising materials due to their easy diffusion path for alkali metals. Specifically, Na x CoO 2 can be regarded as an appealing candidate for next-generation sodium-ion batteries (SIBs), but the multiple steps revealed in the potential vs capacity curve have restricted its use. Herein, we report Na x Co 0.9 Ti 0.1 O 2 , synthesized by a high-temperature solid-state method, where 10 % of cobalt was substituted with titanium. Obviously, the number of potential steps found in the galvanostatic curves of Na x CoO 2 has been reduced. The electrode material exhibits an initial charge capacity of 108 mAh/g within the potential window 2-4.2 V (vs. Na + /Na). The intercalation/deintercalation of Na x Co 0.9 Ti 0.1 O 2 was investigated by in situ synchrotron X-ray diffraction (SXRD), and the results demonstrated a combined solid solution and pseudocapacitive mechanism, where the pseudocapacitive behavior is predominant in the region from 3.73 V (charge) to 3.79 V (discharge). Finally, in situ electrochemical impedance spectroscopy has revealed an increasing impedance, specifically when inserting sodium into the structure.

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Passivation Layer and Cathodic Redox Reactions in Sodium‐Ion Batteries Probed by HAXPES

Cited by 70 publications

References 73 publications

Influence of Using Metallic Na on the Interfacial and Transport Properties of Na-Ion Batteries

Influence of Using Metallic Na on the Interfacial and Transport Properties of Na-Ion Batteries

Surface analytical approaches to reliably characterize lithium ion battery electrodes

Evidence of a Pseudo‐Capacitive Behavior Combined with an Insertion/Extraction Reaction Upon Cycling of the Positive Electrode Material P2‐Na_xCo_0.9Ti_0.1O₂ for Sodium‐ion Batteries

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Passivation Layer and Cathodic Redox Reactions in Sodium‐Ion Batteries Probed by HAXPES

Cited by 70 publications

References 73 publications

Influence of Using Metallic Na on the Interfacial and Transport Properties of Na-Ion Batteries

Influence of Using Metallic Na on the Interfacial and Transport Properties of Na-Ion Batteries

Surface analytical approaches to reliably characterize lithium ion battery electrodes

Evidence of a Pseudo‐Capacitive Behavior Combined with an Insertion/Extraction Reaction Upon Cycling of the Positive Electrode Material P2‐NaxCo0.9Ti0.1O2 for Sodium‐ion Batteries

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Evidence of a Pseudo‐Capacitive Behavior Combined with an Insertion/Extraction Reaction Upon Cycling of the Positive Electrode Material P2‐Na_xCo_0.9Ti_0.1O₂ for Sodium‐ion Batteries