Insights into the Solubility of Poly(vinylphenothiazine) in Carbonate-Based Battery Electrolytes

Perner, Verena; Diddens, Diddo; Otteny, Fabian; Küpers, Verena; Bieker, Peter; Esser, Birgit; Winter, Martin; Kolek, Martin

doi:10.1021/acsami.0c20012

Cited by 32 publications

(54 citation statements)

References 68 publications

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“…For both polymers, the specific current values significantly decreased after the initial cycle, which indicates a dissolution of the active material in the battery electrolyte upon oxidation. Most of this occurred during the first cycle, but the current values slowly further decreased upon cycling . This is in accordance with former studies on PVMPT -based composite electrodes where the current loss was correlated with UV/vis spectroscopic investigations, and the electrolyte solution was deeply colored. , …”

Section: Resultssupporting

confidence: 91%

“…We could circumvent this dissolution by cross-linking the polymer to X-PVMPT , which allowed access to almost the full theoretical specific capacity of 112 mAh g –1 , corresponding to a one-electron oxidation of each phenothiazine subunit . We recently showed that changing the electrolyte solvent from EC/DMC (1:1) to EC/EMC (3:7) also led to an insolubility of PVMPT in both states B and C , thereby unlocking its full specific capacity paired with a high rate capability and low self-discharge . A change in the heteroatom within the heterocyclic ring system from S to O in poly(3-vinyl- N -methylphenoxazine) or using a poly(norbornene) backbone had reduced the π-interactions between the redox-active groups and provided an indication that the molecular structure of the poly(vinylene) PVMPT is an ideal prerequisite for such interactions.…”

Section: Introductionmentioning

confidence: 99%

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Bridging the Gap between Small Molecular π-Interactions and Their Effect on Phenothiazine-Based Redox Polymers in Organic Batteries

Otteny

Perner

Einholz

et al. 2021

ACS Appl. Energy Mater.

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Organic redox polymers are considered a “greener” alternative as battery electrode materials compared to transition metal oxides. Among these, phenothiazine-based polymers have attracted significant attention due to their high redox potential of 3.5 V vs Li/Li+ and reversible electrochemistry. In addition, phenothiazine units can exhibit mutual π-interactions, which stabilize their oxidized states. In poly(3-vinyl-N-methylphenothiazine) (PVMPT), such π-interactions led to a unique charge/discharge mechanism, involving the dissolution and redeposition of the polymer during cycling, and resulted in an ultrahigh cycling stability. Herein, we investigate these π-interactions in more detail and what effect their suppression by molecular design has on battery performance. Our study includes a dimeric reference compound for PVMPT, polymers with bulky tolyl or mesityl substituents on the phenothiazine units to inhibit π-interactions and alternating copolymers with maleimide groups to increase spatial distancing between phenothiazine groups. UV/vis- and electron paramagnetic resonance (EPR)-spectroscopic as well as electrochemical measurements in composite electrodes demonstrate how the unique structure of PVMPT is instrumental in obtaining a high cycling stability in poly(vinylene) derivatives of phenothiazine.

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Section: Resultssupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Bridging the Gap between Small Molecular π-Interactions and Their Effect on Phenothiazine-Based Redox Polymers in Organic Batteries

Otteny

Perner

Einholz

et al. 2021

ACS Appl. Energy Mater.

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“…The most well‐known p‐type organic cathode materials are conducting polymers (e. g., polyaniline, [11,12] polytriphenylamine, [13] and polypyrrole [14] ) and nitroxyl radical polymers (e. g., PTMA [15] ). In recent years, researchers’ interest also shifts to polymers based on various electroactive heteroaromatics, including N ‐substituted phenazine, [16–19] conjugated pyridine dimer, [20] phenothiazine, [18,21–31] phenoxazine, [32] and thianthrene [33,34] . A merit of these heteroaromatic units is that they are potentially able to deliver two electrons and thus achieve attractive capacity above 200 mAh g −1 .…”

Section: Introductionmentioning

confidence: 99%

“…Among these heteroaromatic units, phenothiazine (PTZ) is the most affordable for large‐scale applications and different polymerization methods have been attempted for it. For example, the PTZ units can be hanged as pendants on a robust polymer chain (e. g., PVMPT, [21–23] PVBPT, [25] and PNMPT [27] ), linearly connected or cross‐linked through cross coupling reaction (e. g., poly‐ N ‐propylphenothiazine [28] and HPPT [29] ) or copolymerized with other p‐type units (e. g., P1b [30] and PT‐DMPD [31] ). Although these studies provide general understanding about the redox behavior of PTZ‐based polymers, the reversible capacities are far away from satisfaction as only few exceed 100 mAh g −1 even at the cost of complicated synthesis.…”

Section: Introductionmentioning

confidence: 99%

Facile Synthesis of Polyphenothiazine as a High‐Performance p‐Type Cathode for Rechargeable Lithium Batteries

Wang

Han

et al. 2021

ChemSusChem

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p‐Type electroactive polymers are promising cathodes for dual‐ion batteries but cost‐effective candidates are still lacking. In this study, the p‐type polymer polyphenothiazine (PPTZ) is synthesized by a facile one‐step oxidation polymerization from the low‐cost phenothiazine (PTZ) monomer. As a cathode for rechargeable lithium batteries, PPTZ shows superior electrochemical performance to previously reported PTZ‐based polymers with complicated structures and syntheses. For example, PPTZ has a high reversible capacity of 157 mAh g−1 within 2.5–4.3 V vs. Li+/Li with an average discharge voltage of 3.5 V, and a high capacity retention of 77 % after 500 cycles. The highly reversible one‐electron redox mechanism of PPTZ is also investigated in detail by electrochemical testing, ex situ FT‐IR and X‐ray photoelectron spectroscopy, and DFT calculations. PPTZ has the potential to serve as an attractive p‐type cathode material for practical applications and the facile synthesis may be also extended to other polymer cathodes based on N‐heteroaromatic units.

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“…Solubility of supercritical CO 2 in polymers is the key factor affecting the performance of foamed materials and also widely used in the extraction and separation of various chemicals and the preparation and modification of new materials, displaying good prospects in theoretical research and application [1][2][3][4][5][6]. Under the supercritical conditions of high temperature and high pressure, the dissolution behaviour is affected by many factors and shows nonlinear, non-equilibrium, dynamic and critical properties, which result in the difficulty in the study of dissolution experiments [7][8][9][10][11][12][13][14][15]. The current information technology and artificial intelligence have provided theoretical and technical support for the calculation and simulation of material properties.…”

Section: Introductionmentioning

confidence: 99%

A double-population chaotic self-adaptive evolutionary dynamics model for the prediction of supercritical carbon dioxide solubility in polymers

Yan

Zhang

et al. 2022

R. Soc. open sci.

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Solubility of gas in polymers is an important physico-chemical property of foam materials and widely used in the preparation and modification of new materials. Under the conditions of high temperature and high pressure, the dissolution process is a nonlinear, non-equilibrium and dynamic process, so it is difficult to establish an accurate solubility calculation model. Inspired by particle dynamics and evolutionary algorithm, this paper proposes a hybrid model based on chaotic self-adaptive particle dynamics evolutionary algorithm (CSA-PD-EA), which can use the iterative process of particles in evolutionary algorithms at the dynamic level to simulate the mutual diffusion process of molecules during dissolution. The predicted solubility of supercritical CO 2 in poly(d,l-lactide- co -glycolide), poly(l-lactide) and poly(vinyl acetate) indicated that the comprehensive prediction performance of the CSA-PD-EA model was high. The calculation error and correlation coefficient were, respectively, 0.3842 and 0.9187. The CSA-PD-EA model showed prominent advantages in accuracy, efficiency and correlation over other computational models, and its calculation time was 4.144–15.012% of that of other dynamic models. The CSA-PD-EA model has wide application prospects in the computation of physical and chemical properties and can provide the basis for the theoretical calculation of multi-scale complex systems in chemistry, materials, biology and physics.

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Insights into the Solubility of Poly(vinylphenothiazine) in Carbonate-Based Battery Electrolytes

Cited by 32 publications

References 68 publications

Bridging the Gap between Small Molecular π-Interactions and Their Effect on Phenothiazine-Based Redox Polymers in Organic Batteries

Bridging the Gap between Small Molecular π-Interactions and Their Effect on Phenothiazine-Based Redox Polymers in Organic Batteries

Facile Synthesis of Polyphenothiazine as a High‐Performance p‐Type Cathode for Rechargeable Lithium Batteries

A double-population chaotic self-adaptive evolutionary dynamics model for the prediction of supercritical carbon dioxide solubility in polymers

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