Cooperative Conformational Change of a Single Organic Molecule for Ultrafast Rechargeable Batteries

Son, Giyeong; Ri, Vitalii; Noh, Chanwoo; Yoon, Hongkwan; Ko, Sunghyun; Moon, Joonhee; Jung, YounJoon; Park, Chan Beum; Kim, Chunjoong

doi:10.1021/acsenergylett.1c00560

Cited by 16 publications

(11 citation statements)

References 45 publications

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“…[ 29 ] The capture ability of O‐1 to H atoms is boosted to deliver a binding energy of −4.38 eV (Figure 5i), indicating the robust electrochemically reactivity of carbonyl group. [ 30 ] In addition, top (Figure 5j) and side (Figure S13, Supporting Information) views of the electron density difference were demonstrated by subtracting the charge densities of H and C atoms from N‐6, N‐5, and O‐1 to understand the bonding nature of the adsorbed H atoms in depth. The charge depletion of H and much charge accumulation around N/O active regions are explicitly observed.…”

Section: Resultsmentioning

confidence: 99%

Self‐Assembled Carbon Superstructures Achieving Ultra‐Stable and Fast Proton‐Coupled Charge Storage Kinetics

et al. 2021

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electrochemistry, carbon-based materials have been widely used as electrodes for energy storage devices such as supercapacitors and Zn-ion hybrid capacitors. [1] Electrical energy can be stored through reversible electrosorption of charged species at the carbon-electrolyte interface, enabling fast energy harvesting/delivering in seconds and theoretical work lifespan of more than a million cycles. [2] Crafting intrinsic heterogeneous electrochemically active sites within carbon framework can contribute additional pseudocapacitance, further boosting the energy storage performance. [3] Unfortunately, this scenario is always accompanied with sluggish electrochemistry kinetics and degenerated scaffold firmness caused by heteroatomic motifs, triggering dramatic activity loss and insufficient power/cycle durability. [4] As a result, it is difficult for the fabricated devices to achieve millions of cycles in theory. In fact, the presently reported service life of carbon-based devices is rarely more than 200 000 cycles, especially at large current rates. The surface chemistry, although crucial, affects the charge transfer dynamics and functionality redox responses of carbon electrodes in a chemistry sensitive/influenced process only if that chemistry is accessible for the electrolyte ions. [5] Threedimensional carbon superstructures constructed from the assembly of low-dimensional segments constitute attractive prospects for energy applications. [6] This is because the superstructures inherit the desirable features of their building blocks and gain certain extra unconventional advantages, such as exceptional skeleton robustness, more exposed electroactive sites, and fast ion transfer kinetics. [7] Therefore, it is essential to fundamentally design stable carbon superstructures to allow the high availability of heteroatomic motifs and efficient ion migration with lower energy hurdles, for comprehensively improving device performances to match the expected energy storage target.The selection of small molecules with customized chemical structure, composition and self-assembly behavior as alternative precursors to design functionalized carbons is still an interesting and ongoing work to maximize their applications in energy storage. [7a,8] The triazine unit, a strong electroactive building block, features with highly stable CN covalent bonds Designing ingenious and stable carbon nanostructures is critical but still challenging for use in energy storage devices with superior electrochemistry kinetics, durable capacitive activity, and high rate survivability. To pursue the objective, a simple self-assembly strategy is developed to access carbon superstructures built of nanoparticle embedded plates. The carbon precursors, 2,4,6-trichloro-1,3,5-triazine and 2,6-diaminoanthraquinone can form porous organic polymer with "protic salt"-type rigid skeleton linked by −NH 2 + Cl − − "rivets", which provides the cornerstone for hydrogen-bondingguided self-assembly of the organic backbone to superstructures by π−π plane stacking...

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Section: Resultsmentioning

confidence: 99%

Self‐Assembled Carbon Superstructures Achieving Ultra‐Stable and Fast Proton‐Coupled Charge Storage Kinetics

et al. 2021

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“…The authors evidenced a competition of H + ions for the same chelating groups (negative charged groups) of GAL ox 2– species. Li-ion pairing and H + ion transfer competition was also observed during the reduction process of a phenoxazine-3-one structure used in Li-ion batteries . To be consistent with such reported mechanism, the next set of chemical and electrochemical equations are proposed to explain a competition mechanism during the reduction process of GAL ox 2– species in solution ( sol ), GAL ox(sol) 2– , to form reduced ( red ) species, GAL red(sol) 4– , in hydroxide salt solutions which provide n number of protons H + and positive charged counterions M + (K + , Na + and Li + ): boldGAL ox ( sol ) 2 − + 2 normale − ⇌ boldGAL red ( sol ) 4 − goodbreak0em1em⁣ E 0 , k normals boldGAL red ( sol ) 4 − + n normalM + ⇌ normalM italicn boldGAL red ( sol ) n − 4 goodbreak0em1em⁣ K ion = k normalf 1 / k normalb 1 boldGAL red ( sol ) 4 − + …”

Section: Resultsmentioning

confidence: 74%

“…The authors evidenced a competition of H + ions for the same chelating groups (negative charged groups) of GAL ox 2– species. Li-ion pairing and H + ion transfer competition was also observed during the reduction process of a phenoxazine-3-one structure used in Li-ion batteries . To be consistent with such reported mechanism, the next set of chemical and electrochemical equations are proposed to explain a competition mechanism during the reduction process of GAL ox 2– species in solution ( sol ), GAL ox(sol) 2– , to form reduced ( red ) species, GAL red(sol) 4– , in hydroxide salt solutions which provide n number of protons H + and positive charged counterions M + (K + , Na + and Li + ): Regardless of the number of H + and M + ions interacting with each reduced GAL red(sol) 4– species to form M n GAL red(sol) n –4 and/or H n GAL red(sol) n –4 aggregates, both ion pairing and proton transfer reactions should occur as a fast and reversible process, since no significant changes in the shape and height of E pa signal are observed when modifying the amount of hydroxide salt and/or neutral salt in solution.…”

Section: Resultsmentioning

confidence: 74%

“…Li-ion pairing and H + ion transfer competition was also observed during the reduction process of a phenoxazine-3-one structure used in Li-ion batteries. 43 To be consistent with such reported mechanism, the next set of chemical and electrochemical equations are proposed to explain a competition mechanism during the reduction process of GAL ox 2− species in solution (sol), GAL ox(sol) 2− , to form reduced (red) species, GAL red(sol) 4− , in hydroxide salt solutions which provide n number of protons H + and positive charged counterions M + (K + , Na + and Li + ):…”

Section: ■ Introductionmentioning

confidence: 99%

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Reversible Redox Chemistry in a Phenoxazine-Based Organic Compound: A Two-Electron Storage Negolyte for Alkaline Flow Batteries

Martínez‐González

Amador‐Bedolla

Ugalde‐Saldívar

2022

ACS Appl. Energy Mater.

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Finding two-electron storage aqueous organic negolytes is crucial for increasing the charge storage capacity in next-generation flow batteries. Inspired by the ability of gallocyanine compound (GAL) to act as an efficient two-electron transfer mediator in biology, we investigated its reduction process by cyclic voltammetry at alkaline conditions, detecting ion pairing (with Na+, K+, or Li+ ions) and H+ transfer pathways in electrogenerated species. The voltammetric responses obtained were dependent on the concentrations of analyte and supporting electrolyte and exhibited values of peak-to-peak potential distance (ΔE p) close to the limiting value established in flow battery protocols for screening irreversible systems (>200/n mV). The results presented in this work can not be explained by irreversible mechanisms. This atypical behavior was related to the evolution of a mixed and reversible process of adsorption and diffusion pathways, where GAL species near the electrode first attach to the electroactive surface without passivating it, so at high concentrations of GAL compound, the reactions can take place by a mainly diffusive process (at the modified electrode). The reversible redox chemistry in compound studied was corroborated by testing a flow cell of 0.83 V composed of a GAL-KOH system and the posolyte ferrocyanide-KOH solution. The cell exhibited a Coulombic efficiency close to 100% and retained 87% of its capacity after 200 charge–discharge cell cycles. This is the first report concerning the use of a phenoxazine-based derivative for storing two electrons per molecule in an aqueous flow cell.

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“…The primary factor is the durability of the organic host molecular conformation with ion compositional variation during redox‐interconversions and vital kinetics of ion diffusions (insertion/desertions) to obtain optimal organic batteries. [ 8 ] Moreover, redox processes during charging/discharging are supposed to be perfectly reversible and chemically tunable with multiple oxidation states, furnishing the characteristic electrochemistry.…”

Section: Introductionmentioning

confidence: 99%

Octaphyrin(1.0.1.0.1.0.1.0) as an Organic Electrode for Li and Na Rechargeable Batteries

et al. 2021

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resources, being the fourth most abundant element. [4] LIBs and NIBs gathered complementary scientific attention due to being earth-abundant eco-friendly, economic elements. [7] However, amendment of the robustness of organic electrode materials during lithiation/delithiation (or sodiation/desodiation), dissolution in the conventional organic electrolytes (carbonated electrolyte) and low electronic conductivity have been the central issue towards practical energy storage systems.The primary factor is the durability of the organic host molecular conformation with ion compositional variation during redox-interconversions and vital kinetics of ion diffusions (insertion/desertions) to obtain optimal organic batteries. [8] Moreover, redox processes during charging/ discharging are supposed to be perfectly reversible and chemically tunable with multiple oxidation states, furnishing the characteristic electrochemistry.Our preliminary study on the organic electrode materials of nickel(II) norcorrole (NiNc), exhibiting antiaromatic character, has been adopted for alkali metal-organic batteries. [9][10] The Li-and Na-NiNc cells afforded high durability, high discharge capacity, and high Coulombic efficiency with vital electromagnetic properties of antiaromaticity. In general, antiaromatic compounds are volatile, easily mutable, and are propounded to tilt to more stable molecular conformations impulsively. [11] However, marvelously, the norcorrole molecule stabilizes the antiaromaticity due to the tetradentate-metal coordination with Ni(II), while still preserving its antiaromatic properties persistently. [12] Well-organized interconversions between antiaromatic and aromatic conformations along with redox reactions are intrinsically parts of the battery performance in Li-and Na-NiNc batteries. An increase of cyclic rings contributing to the π-delocalized system implied less negative states of energy and the highest tendency to interact with liquid ions. [13] It is highly probable that the vital key to the feasibility of implementing the infinite redox process depends on the effectiveness of π-delocalizations and sequential stabilizations of the redox states.Extended π-conjugations enable secure interactions with shuttling ions during redox processes. It can spread electron density over the whole molecular π-system, which makes it suitable for stabilizing the electron addition and subtraction states due to consequent charge-delocalization. [14] The preliminary study on the Li-organic energy-storage devices with the Organic electrode materials for rechargeable batteries have come into the spotlight due to their structural tunability and diversity. In this study, it is found that bisnickel(II) meso-mesityloctaphyrin( 1.0.1.0.1.0.1.0) (Oct) is exhibiting multiple oxidation states with extended π-conjugation pathways to afford an active electrode material in Li and Na-organic batteries and secure interactions with Li + (or Na + ) and anions enabling efficient dual ionic charge/ discharge behaviors. Cyclic voltammograms of the Oc...

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Cooperative Conformational Change of a Single Organic Molecule for Ultrafast Rechargeable Batteries

Cited by 16 publications

References 45 publications

Self‐Assembled Carbon Superstructures Achieving Ultra‐Stable and Fast Proton‐Coupled Charge Storage Kinetics

Self‐Assembled Carbon Superstructures Achieving Ultra‐Stable and Fast Proton‐Coupled Charge Storage Kinetics

Reversible Redox Chemistry in a Phenoxazine-Based Organic Compound: A Two-Electron Storage Negolyte for Alkaline Flow Batteries

Octaphyrin(1.0.1.0.1.0.1.0) as an Organic Electrode for Li and Na Rechargeable Batteries

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