Structure formation and surface chemistry of ionic liquids on model electrode surfaces—Model studies for the electrode | electrolyte interface in Li-ion batteries

Büchner, Florian; Uhl, Benedikt; Forster-Tonigold, Katrin; Bansmann, Joachim; Groß, Axel; Behm, R. Jürgen

doi:10.1063/1.5012878

Cited by 21 publications

(61 citation statements)

References 86 publications

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“…On lithiated HOPG, this was explained by the complete desorption of EC at low temperatures (≈200 K), where the mobility of Li + in the bulk of lithiated HOPG is too low to segregate toward the surface and react with the adsorbate phase . We recently demonstrated that Li can in fact easily deintercalate from the bulk of lithiated HOPG, but only at temperatures higher than 230 K and only in the presence of a strongly adsorbed species such as an ionic liquid adlayer (desorption temperature >400 K), which chemically stabilizes the surface Li …”

Section: Resultsmentioning

confidence: 99%

“…One possible way to determine the initial stages of the SEI formation at the EEI at the atomic/molecular level involves the use of surface science techniques, studying the interaction of individual components of electrolytes, such as the typical key component EC (or other electrolyte components like ionic liquids), with well‐defined model electrodes under idealized ultrahigh‐vacuum (UHV) conditions, which is focus of the ongoing work in our laboratory. Following a previous study on the interaction of EC with Li‐free and lithiated highly oriented pyrolytic graphite (HOPG) as model for the anode, we here report the results of a similar type of study on the interaction of EC with well‐defined LiCoO 2 electrode surfaces, both fully oxidized LiCoO 2 and partly reduced LiCoO 2− δ surfaces, as models for the cathode.…”

Section: Introductionmentioning

confidence: 99%

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Interaction of Ultrathin Films of Ethylene Carbonate with Oxidized and Reduced Lithium Cobalt Oxide—A Model Study of the Cathode|Electrolyte Interface in Li‐Ion Batteries

Büchner

Fingerle

Kim

et al. 2018

Adv Materials Inter

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Li-ion batteries (LIBs). [1][2][3][4][5][6][7][8][9] One of the most crucial parts for their performance and lifetime is the interfacial layer between electrodes and electrolyte, the so-called solid|electrolyte interphase (SEI) at the electrode|electrolyte interface (EEI), which is formed during initial battery operation. [10][11][12][13][14][15] It is generated by the decomposition of electrolytes, forming a passivating layer, which is beneficial for the longtime stability of the battery. The detailed atomic/molecular-scale understanding of the SEI formation process is hampered by the complexity of the cell processes participating therein, including the transfer of Li + ions across the interphase, electrolyte reduction/oxidation, and chemical reactions, all of which are expected to play a role in the SEI formation. Furthermore, standard electrolytes usually consist of a mix of several components such as ethylene carbonate (EC), propylene carbonate, diethyl carbonate (DEC), or dimethyl carbonate and a lithium salt such as lithium hexafluorophosphate (LiPF 6 ), [16] which increases the complexity and makes it difficult to identify individual reactions. Furthermore, the processes at the EEI in LIBs are hardly accessible by techniques providing molecularscale information.One possible way to determine the initial stages of the SEI formation at the EEI at the atomic/molecular level involves the use of surface science techniques, studying the interaction of individual components of electrolytes, such as the typical key component EC (or other electrolyte components like ionic liquids), with well-defined model electrodes under idealized ultrahigh-vacuum (UHV) conditions, [17][18][19][20][21][22][23][24][25][26][27][28][29] which is focus of the ongoing work in our laboratory. Following a previous study on the interaction of EC with Li-free and lithiated highly oriented pyrolytic graphite (HOPG) as model for the anode, [17] we here report the results of a similar type of study on the interaction of EC with well-defined LiCoO 2 electrode surfaces, both fully oxidized LiCoO 2 and partly reduced LiCoO 2−δ surfaces, as models for the cathode. These two different types of samples were chosen since they are expected to exist also under application conditions, and since the oxidation state is expected to influence also their reactivity. Aiming at a detailed, molecular-scale understanding of the initial stages of the solid|electrolyte interphase (SEI) formation in Li-ion batteries, the interaction of the common electrolyte solvent component ethylene carbonate (EC)with fully lithiated LiCoO 2 and reduced LiCoO 2−δ films as model electrodes for the cathode is investigated. The results are compared with previous findings for pristine and lithiated highly oriented pyrolytic graphite, serving as model anode. Employing X-ray photoelectron spectroscopy (XPS) and ultraviolet photoelectron spectroscopy measurements, it is found that vapor deposition of EC on LiCoO 2 and LiCoO 2−δ at 80 K results in molecularly adsorbed EC, both in the mon...

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Interaction of Ultrathin Films of Ethylene Carbonate with Oxidized and Reduced Lithium Cobalt Oxide—A Model Study of the Cathode|Electrolyte Interface in Li‐Ion Batteries

Büchner

Fingerle

Kim

et al. 2018

Adv Materials Inter

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“…A highly oriented pyrolytic graphite test substrate cooled to 80 K (no intercalation) was used for calibration of the Li deposition rate. [14] Deposition rates in MLE of approximately 0.04-0.05 MLE min À 1 were calculated from the damping of the C 1s substrate) peak after successive vapor deposition of Li at temperatures where Li adsorbs on the surface. For the evaluation we assume that 1 MLE of Li has a thickness d of 2.48 Å, equivalent to the (110) interplanar distance in a body centered cubic lattice (the most stable configuration of a Li metal at r.t.).…”

Section: Methodsmentioning

confidence: 99%

“…Therefore, in our model approach, we reduced the complexity significantly, and prepare well-defined model electrodes like Co 3 O 4 (111) thin film electrodes, under idealized ultrahigh vacuum (UHV) conditions, and explore the interaction of individual components of the battery electrolyte (e. g., ionic liquids, carbonates, lithium) using surface science techniques. [11][12][13][14][15][16][17][18] In particular ionic liquids (ILs), [19][20][21][22] that are organic salts with a melting point below 100°C, got into the focus as promising solvents in battery electrolytes, [23][24] as they are, for example, not flammable, such reducing the hazard of battery fires. [25] Consequently, they represent an important class of compounds whose interactions with electrodes need to be studied.…”

Section: Introductionmentioning

confidence: 99%

“…Another first principle calculation by Yao et al [28] identified a stable Li n Co 3 O 4 (n � 3) insertion phase, which preserves a rigid oxygen framework during lithiation and which is proposed to have a constrained volume expansion and enhanced cycling stability at a capacity of~334 mAh g À 1 , before a conversion-type reaction starts above 3 mol of Li per formular unit of Co 3 O 4 . In addition, several model studies were conducted on the interaction of BMP-TFSI with different model electrode surfaces, and after Li exposure, e. g., on Cu(111), [29] a copper foil, [30][31] highly oriented pyrolytic graphite (HOPG), [11,[13][14] TiO 2 (110), [32] Si(111) [33] and very recently on CoO(111). [26] On CoO(111) stepwise post-deposition of small amounts of metallic Li (< one monolayer equivalent (MLE)) to a pre-adsorbed BMP-TFSI adlayer results in the gradual decomposition of BMP-TFSI into several decomposition products such as Li 2 S, LiF, LiC x H y N z Li 2 NSO 2 CF 3 , SO 2 CF 3 .…”

Section: Introductionmentioning

confidence: 99%

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Model Studies on the Formation of the Solid Electrolyte Interphase: Reaction of Li with Ultrathin Adsorbed Ionic‐Liquid Films and Co₃O₄(111) Thin Films

et al. 2021

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In this work we aim towards the molecular understanding of the solid electrolyte interphase (SEI) formation at the electrode electrolyte interface (EEI). Herein, we investigated the interaction between the battery‐relevant ionic liquid (IL) 1‐butyl‐1‐methylpyrrolidinium bis(trifluoromethylsulfonyl)imide (BMP‐TFSI), Li and a Co3O4(111) thin film model anode grown on Ir(100) as a model study of the SEI formation in Li‐ion batteries (LIBs). We employed mostly X‐ray photoelectron spectroscopy (XPS) in combination with dispersion‐corrected density functional theory calculations (DFT‐D3). If the surface is pre‐covered by BMP‐TFSI species (model electrolyte), post‐deposition of Li (Li+ ion shuttle) reveals thermodynamically favorable TFSI decomposition products such as LiCN, Li2NSO2CF3, LiF, Li2S, Li2O2, Li2O, but also kinetic products like Li2NCH3C4H9 or LiNCH3C4H9 of BMP. Simultaneously, Li adsorption and/or lithiation of Co3O4(111) to LinCo3O4 takes place due to insertion via step edges or defects; a partial transformation to CoO cannot be excluded. Formation of Co0 could not be observed in the experiment indicating that surface reaction products and inserted/adsorbed Li at the step edges may inhibit or slow down further Li diffusion into the bulk. This study provides detailed insights of the SEI formation at the EEI, which might be crucial for the improvement of future batteries.

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Multiscale Investigation of Sodium‐Ion Battery Anodes: Analytical Techniques and Applications

Schäfer,

Hankins,

Allion

et al. 2024

Advanced Energy Materials

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The anode/electrolyte interface behavior, and by extension, the overall cell performance of sodium‐ion batteries is determined by a complex interaction of processes that occur at all components of the electrochemical cell across a wide range of size‐ and timescales. Single‐scale studies may provide incomplete insights, as they cannot capture the full picture of this complex and intertwined behavior. Broad, multiscale studies are essential to elucidate these processes. Within this perspectives article, several analytical and theoretical techniques are introduced, and described how they can be combined to provide a more complete and comprehensive understanding of sodium‐ion battery (SIB) performance throughout its lifetime, with a special focus on the interfaces of hard carbon anodes. These methods target various length‐ and time scales, ranging from micro to nano, from cell level to atomistic structures, and account for a broad spectrum of physical and (electro)chemical characteristics. Specifically, how mass spectrometric, microscopic, spectroscopic, electrochemical, thermodynamic, and physical methods can be employed to obtain the various types of information required to understand battery behavior will be explored. Ways are then discussed how these methods can be coupled together in order to elucidate the multiscale phenomena at the anode interface and develop a holistic understanding of their relationship to overall sodium‐ion battery function.

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Structure formation and surface chemistry of ionic liquids on model electrode surfaces—Model studies for the electrode | electrolyte interface in Li-ion batteries

Cited by 21 publications

References 86 publications

Interaction of Ultrathin Films of Ethylene Carbonate with Oxidized and Reduced Lithium Cobalt Oxide—A Model Study of the Cathode|Electrolyte Interface in Li‐Ion Batteries

Interaction of Ultrathin Films of Ethylene Carbonate with Oxidized and Reduced Lithium Cobalt Oxide—A Model Study of the Cathode|Electrolyte Interface in Li‐Ion Batteries

Model Studies on the Formation of the Solid Electrolyte Interphase: Reaction of Li with Ultrathin Adsorbed Ionic‐Liquid Films and Co₃O₄(111) Thin Films

Multiscale Investigation of Sodium‐Ion Battery Anodes: Analytical Techniques and Applications

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Structure formation and surface chemistry of ionic liquids on model electrode surfaces—Model studies for the electrode | electrolyte interface in Li-ion batteries

Cited by 21 publications

References 86 publications

Interaction of Ultrathin Films of Ethylene Carbonate with Oxidized and Reduced Lithium Cobalt Oxide—A Model Study of the Cathode|Electrolyte Interface in Li‐Ion Batteries

Interaction of Ultrathin Films of Ethylene Carbonate with Oxidized and Reduced Lithium Cobalt Oxide—A Model Study of the Cathode|Electrolyte Interface in Li‐Ion Batteries

Model Studies on the Formation of the Solid Electrolyte Interphase: Reaction of Li with Ultrathin Adsorbed Ionic‐Liquid Films and Co3O4(111) Thin Films

Multiscale Investigation of Sodium‐Ion Battery Anodes: Analytical Techniques and Applications

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Model Studies on the Formation of the Solid Electrolyte Interphase: Reaction of Li with Ultrathin Adsorbed Ionic‐Liquid Films and Co₃O₄(111) Thin Films