Further Insights into Structural Diversity of Phosphorus-Based Decomposition Products in Lithium Ion Battery Electrolytes via Liquid Chromatographic Techniques Hyphenated to Ion Trap-Time-of-Flight Mass Spectrometry

Henschel, Jonas; Schwarz, J. Luca; Glorius, Frank; Winter, Martin; Nowak, Sascha

doi:10.1021/acs.analchem.8b05229

Cited by 30 publications

(27 citation statements)

References 62 publications

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“…On the one hand, disproportionation can be accelerated at higher temperatures and, on the other hand, more acidic compounds can be formed at higher temperatures due to accelerated decomposition of the thermal labile conducting salt LiPF 6 . Previous studies demonstrated the decomposition of organic carbonates and the conducting salt at elevated temperatures to different acids, like HF or difluorophosphoric acid, especially in the presence of moisture [63–69]. As a consequence, LNMO particles are situated under acidic condition, which was shown to increase the dissolution of manganese [18, 21, 31, 34, 35].…”

Section: Resultsmentioning

confidence: 99%

Mn²⁺ or Mn³⁺? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresis

et al. 2020

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Mn 2+ or Mn 3+ ? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresisA new CE method with ultraviolet-visible detection was developed in this study to investigate manganese dissolution in lithium ion battery electrolytes. The aqueous running buffer based on diphosphate showed excellent stabilization of labile Mn 3+ , even under electrophoretic conditions. The method was optimized regarding the concentration of diphosphate and modifier to obtain suitable signals for quantification. Additionally, the finally obtained method was applied on carbonate-based electrolytes samples. Dissolution experiments of the cathode material LiNi 0.5 Mn 1.5 O 4 (lithium nickel manganese oxide [LNMO]) in aqueous diphosphate buffer at defined pH were performed to investigate the effect of a transition metal-ion-scavenger on the oxidation state of dissolved manganese. Quantification of both Mn species revealed the formation of mainly Mn 3+ , which can be attributed to a comproportionation reaction of dissolved and complexed Mn 2+ with Mn 4+ at the surface of the LNMO structure. It was also shown that the formation of Mn 3+ increased with lower pH. In contrast, dissolution experiments of LNMO in carbonate-based electrolytes containing LIPF 6 showed only dissolution of Mn 2+ .Abbreviations: LIBs, lithium ion batteries; LMO, lithium manganese oxide; LNMO, lithium nickel manganese oxide; SEI, solid electrolyte interphase; TM, transition metal; XANES, Xray absorption near-edge structure spectroscopy Color online: See the article online to view Figs. 1-5 in color.

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Section: Resultsmentioning

confidence: 99%

Mn²⁺ or Mn³⁺? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresis

et al. 2020

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“…The proposed reactive species monoglycolate methyl/ethyl carbonate was claimed the key compound for the initiation of the decomposition (“intermediary A”) . The decomposition of LiPF 6 ‐based electrolytes to organo(fluoro)phosphates (O(F)Ps) was investigated intensively . Subsequent studies addressed reductively and oxidatively generated products and evolving gases separately as well as the identification of further decomposition compounds …”

Section: Introductionmentioning

confidence: 99%

Clarification of Decomposition Pathways in a State‐of‐the‐Art Lithium Ion Battery Electrolyte through ¹³C‐Labeling of Electrolyte Components

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The decomposition of state‐of‐the‐art lithium ion battery (LIB) electrolytes leads to a highly complex mixture during battery cell operation. Furthermore, thermal strain by e.g., fast charging can initiate the degradation and generate various compounds. The correlation of electrolyte decomposition products and LIB performance fading over life‐time is mainly unknown. The thermal and electrochemical degradation in electrolytes comprising 1 m LiPF6 dissolved in 13C3‐labeled ethylene carbonate (EC) and unlabeled diethyl carbonate is investigated and the corresponding reaction pathways are postulated. Furthermore, a fragmentation mechanism assumption for oligomeric compounds is depicted. Soluble decomposition products classes are examined and evaluated with liquid chromatography‐high resolution mass spectrometry. This study proposes a formation scheme for oligo phosphates as well as contradictory findings regarding phosphate‐carbonates, disproving monoglycolate methyl/ethyl carbonate as the central reactive species.

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“…Since only the terminated products (blue background) were accessible for LC-MS measurements,the explicit initiation reaction and elongation cascade were postulated to match the obtained results.T o generate further insights into the presence of reactive species, the application of in situ techniques (e.g., IR, Raman and NMR) are possible approaches but will face challenges regarding sensitivity as well as the reliable assignment of signals without chromatographic separation in the highly complex mixture of decomposition products in LIB electrolytes with > 300 possible compounds. [25,34,35] Possible unlabeled termination molecules were DEC and lithium alkoxides (originating from DEC). Resulting leaving groups were postulated stoichiometrically.…”

Section: Thermal Agingmentioning

confidence: 99%

“…[28,29] Besides electrochemical decomposition, thermal stress at elevated temperatures (60-80 8 8C) is another reason for aring opening polymerization of ethylene carbonate (EC) and acomparable variety of species. [25,[30][31][32][33] Overall, the identified soluble compound classes in electrolytes covered (i)o ligo carbonates,(ii)carbonate ether co-oligomers,(iii)glycols,(iv) O(F)Ps,(v) phosphate-carbonate-intermixtures and (vi)oligo phosphates,r esulting in various different species. [25,28,29,34,35] Particularly,the decomposition route to oligo phosphates via "intermediary A" was difficult to define.Recently,W ang, Xu, Eichhorn and co-workers corrected the previous assumption of lithium ethyl di-carbonate (LEDC) as am ain SEI component to the analogous monocarbonate species.…”

Section: Introductionmentioning

confidence: 99%

“…[19] Thed ecomposition of LiPF 6 -based electrolytes to organo(fluoro)phosphates (O(F)Ps) was investigated intensively. [22][23][24][25] Subsequent studies addressed reductively and oxidatively generated products and evolving gases separately [26,27] as well as the identification of further decomposition compounds. [28,29] Besides electrochemical decomposition, thermal stress at elevated temperatures (60-80 8 8C) is another reason for aring opening polymerization of ethylene carbonate (EC) and acomparable variety of species.…”

Section: Introductionmentioning

confidence: 99%

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Clarification of Decomposition Pathways in a State‐of‐the‐Art Lithium Ion Battery Electrolyte through ¹³C‐Labeling of Electrolyte Components

et al. 2020

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Further Insights into Structural Diversity of Phosphorus-Based Decomposition Products in Lithium Ion Battery Electrolytes via Liquid Chromatographic Techniques Hyphenated to Ion Trap-Time-of-Flight Mass Spectrometry

Cited by 30 publications

References 62 publications

Mn²⁺ or Mn³⁺? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresis

Mn²⁺ or Mn³⁺? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresis

Clarification of Decomposition Pathways in a State‐of‐the‐Art Lithium Ion Battery Electrolyte through ¹³C‐Labeling of Electrolyte Components

Clarification of Decomposition Pathways in a State‐of‐the‐Art Lithium Ion Battery Electrolyte through ¹³C‐Labeling of Electrolyte Components

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Further Insights into Structural Diversity of Phosphorus-Based Decomposition Products in Lithium Ion Battery Electrolytes via Liquid Chromatographic Techniques Hyphenated to Ion Trap-Time-of-Flight Mass Spectrometry

Cited by 30 publications

References 62 publications

Mn2+ or Mn3+? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresis

Mn2+ or Mn3+? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresis

Clarification of Decomposition Pathways in a State‐of‐the‐Art Lithium Ion Battery Electrolyte through 13C‐Labeling of Electrolyte Components

Clarification of Decomposition Pathways in a State‐of‐the‐Art Lithium Ion Battery Electrolyte through 13C‐Labeling of Electrolyte Components

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Mn²⁺ or Mn³⁺? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresis

Mn²⁺ or Mn³⁺? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresis

Clarification of Decomposition Pathways in a State‐of‐the‐Art Lithium Ion Battery Electrolyte through ¹³C‐Labeling of Electrolyte Components

Clarification of Decomposition Pathways in a State‐of‐the‐Art Lithium Ion Battery Electrolyte through ¹³C‐Labeling of Electrolyte Components