Organic Negative Electrode Materials for Metal‐Ion and Molecular‐Ion Batteries: Progress and Challenges from a Molecular Engineering Perspective

Lakraychi, Alae Eddine; Dolhem, Franck; Vlad, Alexandru; Bécuwe, Matthieu

doi:10.1002/aenm.202101562

Cited by 49 publications

(55 citation statements)

References 266 publications

(431 reference statements)

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“…Organic electrode materials are emerging as potential candidates for electrochemical energy storage applications with most appealing features such as natural abundance, sustainability and lower environmental footprints. [1][2][3][4] The modern battery technologies are heavily dependent on transition metal oxides electrode materials which are procured after extensive mining and expensive synthesis protocols such as energy consuming high temperature processing. Moreover, material cost, handling and recycling encourage the efforts towards development of organic electrode materials.…”

Section: Introductionmentioning

confidence: 99%

Revealing the Solid-State Electrochemistry of Conjugated Oximates: Towards a New Functionality for Organic Batteries

Wang

Apostol

Rambabu

et al. 2022

Preprint

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In the rising advent of organic Li-ion cathodes with practical characteristic of being air-stable while in the reduced lithium-reservoir form, we report herein a new class of organic Li-ion positive electrode materials - the conjugated oximate lithium salts. The solid-phase electrochemistry of first five examples of the oximate class, including cyclic (aromatic), acyclic (non-aromatic), aliphatic and tetra-functional stereotypes, uncovers the complex interplay between the molecular structure and the electroactivity in the solid phase, as well as the potential of this rich family as cathode materials for lithium-ion batteries. The conjugation of oximate functions within the molecular core is found to endow excellent air stability of lithiated reduced phases, an important prerequisite for practical use as Li-ion positive electrode materials. Amongst the exotic features characterizing the solid-state electrochemistry of this class of materials, the most appealing one belongs to the reversible solid-state polymerization through intermolecular azodioxy coupling (-ONNO-) and the intramolecular furoxan cyclization of their oxidized forms. In the disclosed series of materials, the best performing candidate delivers high reversible capacity of 357 at an average potential of 3.0 vs. Li+/Li0, attaining over 1 KWh kg-1 specific energy content.

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Section: Introductionmentioning

confidence: 99%

Revealing the Solid-State Electrochemistry of Conjugated Oximates: Towards a New Functionality for Organic Batteries

Wang

Apostol

Rambabu

et al. 2022

Preprint

Self Cite

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“…A common approach to improve the cycling stability of the redox-active small molecules is to covalently bond them to a polymer backbone in order to reduce their solubility into the electrolyte. Consequently, redox polymers have attracted a lot of attention as electrode materials for energy storage application, due to their inherent features such as enhanced cycling stability, high rate performance, processability (i.e., extrusion, roll-to-roll and 2D/3D-printing processes), flexibility, recyclability and their potential to be derived from biomass resources [8][9][10][11][12]. In addition, redox polymers are considered as a promising alternative to the scarce inorganic electrode materials that are currently used in Li-ion battery technology [13,14], as they are essentially composed of naturally abundant elements (i.e., carbon, hydrogen, oxygen, nitrogen and sulphur) [10].…”

Section: Introductionmentioning

confidence: 99%

“…The design of redox polymers with lower redox potential, which is appealing in term of the energy density output of the electrochemical devices, is a more challenging task, with so far less diversity available in terms of redox chemistry. Most organic anode materials reported to date are based on conjugated dicarboxylates, Schiff bases, conjugated azo groups and viologens moieties [12]. Finally, redox polymers can be designed using a wide range of polymerization methods such as free-radical polymerization, controlled radical polymerization or emulsion polymerization, allowing high tuneability of their macromolecular architecture to suit application requirements.…”

Section: Introductionmentioning

confidence: 99%

Chemical Upcycling of PET Waste towards Terephthalate Redox Nanoparticles for Energy Storage

Goujon

Demarteau

Pariza

et al. 2021

Sustainable Chemistry

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Over 30 million ton of poly(ethylene terephthalate) (PET) is produced each year and no more than 60% of all PET bottles are reclaimed for recycling due to material property deteriorations during the mechanical recycling process. Herein, a sustainable approach is proposed to produce redox-active nanoparticles via the chemical upcycling of poly(ethylene terephthalate) (PET) waste for application in energy storage. Redox-active nanoparticles of sizes lower than 100 nm were prepared by emulsion polymerization of a methacrylic-terephthalate monomer obtained by a simple methacrylate functionalization of the depolymerization product of PET (i.e., bis-hydroxy(2-ethyl) terephthalate, BHET). The initial cyclic voltammetry results of the depolymerization product of PET used as a model compound show a reversible redox process, when using a 0.1 M tetrabutylammonium hexafluorophosphate/dimethyl sulfoxide electrolyte system, with a standard redox potential of −2.12 V vs. Fc/Fc+. Finally, the cycling performance of terephthalate nanoparticles was investigated using a 0.1 M TBAPF6 solution in acetonitrile as electrolyte in a three-electrode cell. The terephthalate anode electrode displays good cycling stability and performance at high C-rate (i.e., ≥5C), delivering a stable specific discharge capacity of 32.8 mAh.g−1 at a C-rate of 30 C, with a capacity retention of 94% after 100 cycles. However, a large hysteresis between the specific discharge and charge capacities and capacity fading are observed at lower C-rate (i.e., ≤2C), suggesting some irreversibility of redox reactions associated with the terephthalate moiety, in particular related to the oxidation process.

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“…[ 1–3 ] Ever since Sony Co. commercialized the world's first LIBs with a tailor‐made carbon negative electrode, [ 4 ] great efforts have been devoted to exploring novel energy storage materials. [ 5–20 ] Graphite is commonplace among commercial LIBs because of low redox potential, good stability and electrical conductivity. The electrochemical de/lithiation process, known as de/intercalation, is the mechanism through which graphite is able to store lithium.…”

Section: Introductionmentioning

confidence: 99%

“…The rapidly evolving market of electrically powered vehicles and portable electronics drives a great demand for electrochemical energy storage devices with enhanced tailor-made carbon negative electrode, [4] great efforts have been devoted to exploring novel energy storage materials. [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] Graphite is commonplace among commercial LIBs because of low redox potential, good stability and electrical conductivity. The electrochemical de/lithiation process, known as de/intercalation, is the mechanism through which graphite is able to store lithium.…”

Section: Introductionmentioning

confidence: 99%

N‐doped carbon nanotube sponges and their excellent lithium storage performances

et al. 2021

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Preparation, analysis and lithium storage performance of a series of nitrogen‐doped carbon nanotube sponges (CNX) is presented in this work. The synthesis was performed using an aerosol‐assisted chemical vapor deposition (AACVD) in a bi‐sprayer system by using various carbon and nitrogen precursors made of mixtures of benzylamine with toluene, urea, pyridine and 1,2‐dichlorbenzene, with ferrocene as catalyst. A series of physico‐chemical analysis techniques are used to characterize the composition and the morphology of the obtained materials, and a correlation of these with the lithium storage performances is attempted. The samples reveal an interconnected core‐shell CNX fiber morphology with a CNT‐core surrounded by an amorphous carbon shell. Appealing lithium storage performances are attained, while also considering aspects of safety, low potential, and long‐term cycling stability. The best performing sponges display a high specific capacity (223 mAh g−1) when cycled in a practically relevant voltage window (0.01–1V vs. Li), high first cycle (90%) and long‐term cycling (99.3%) coulombic efficiencies and excellent capacity retention after 1500 cycles. This study further analyses the interplay between the morphology and the physico‐chemistry of nitrogen‐doped carbon nanotube materials for Lithium storage and provides guidelines for future developments.

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Organic Negative Electrode Materials for Metal‐Ion and Molecular‐Ion Batteries: Progress and Challenges from a Molecular Engineering Perspective

Cited by 49 publications

References 266 publications

Revealing the Solid-State Electrochemistry of Conjugated Oximates: Towards a New Functionality for Organic Batteries

Revealing the Solid-State Electrochemistry of Conjugated Oximates: Towards a New Functionality for Organic Batteries

Chemical Upcycling of PET Waste towards Terephthalate Redox Nanoparticles for Energy Storage

N‐doped carbon nanotube sponges and their excellent lithium storage performances

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