The Dual Role of Bridging Phenylene in an Extended Bipyridine System for High-Voltage and Stable Two-Electron Storage in Redox Flow Batteries

Pan, Mingguang; Lu, Yan; Lu, Shan Zhen; Yu, Bo; Wan, Jie; Liu, Yuzhu; Jin, Zhong

doi:10.1021/acsami.1c09019

Cited by 42 publications

(44 citation statements)

References 57 publications

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“…This means that the N + on the PBM is difficult to be reduced by gaining electrons, thereby reducing the reduction potential of the PBM. [ 49–53 ] On the basis of these observations, we postulate that PBM interfaces are electrochemically stable even during lithium plating. Besides, the PBM has a Young's modulus of 0.76 GPa (Figure S8, Supporting Information), which ensures PBM a flexibility that can adapt to volume changes during Li plating/stripping.…”

Section: Resultsmentioning

confidence: 90%

Constructing Self‐Adapting Electrostatic Interface on Lithium Metal Anode for Stable 400 Wh kg⁻¹ Pouch Cells

Zhao

Li²,

Chen

et al. 2022

Advanced Energy Materials

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The realization of large‐capacity, high‐energy‐density Li metal battery technology is seriously impeded by dendrite growth and massive dead lithium formation upon cycling. Here, a stable flexible electrostatic self‐adapting polymer (poly(1‐benzyl‐3‐vinylimidazolium), (PBM)) interface is reported to regulate lithium‐ion deposition for dendrite‐free lithium metal batteries. The cationic PBM interlayer can adaptively tune the surface current density near the lithium/electrolyte interface, inducing a uniform distribution of current density and lithium ions and thus achieving dendrite‐free Li deposition under harsh conditions (lean electrolyte 8.75 µL mAh−1, high areal capacity >4 mAh cm−2). Moreover, the tethered phenyl groups endow PBM with a low reduction potential of −3.7 V versus standard hydrogen electrode by decreasing Hirshfeld charge at the reductive site. This avoids electrochemical reduction and therefore ensures the long‐term stability of the PBM interface. Consequently, the Li|PBM@Cu asymmetric cells deliver a high average Coulombic efficiency of 99.38% at 8 mAh cm−2 with lean electrolyte. Notably, the 5.1 Ah LiNi0.8Co0.1Mn0.1O2|PBM@Li pouch cell exhibits excellent cycling stability (0.011% decay/cycle) and high energy density (418.7 Wh kg−1) under realistic conditions (lean electrolyte 2.5 g Ah−1, high areal capacity 5.7 mAh cm−2, and high current density 2.7 mA cm−2).

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Section: Resultsmentioning

confidence: 90%

Constructing Self‐Adapting Electrostatic Interface on Lithium Metal Anode for Stable 400 Wh kg⁻¹ Pouch Cells

Zhao

Li²,

Chen

et al. 2022

Advanced Energy Materials

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“…Interestingly, it is a controversial question that whether a two-electron or two single-electron redox possesses proceed for phenylene bridging bipyridinium derivatives. [37,38] Herein, we propose a simple and effective method to clarify this question. As revealed by the CV curves in Figure S7a, Supporting Information, the one broad redox couple of [PyrPV]Cl 4 was gradually split into two overlapped couples when increasing the concentration of [PyrPV]Cl 4 from 2 to 100 mM in a 2 m NaCl aqueous solution, unambiguously confirming the two single-electron reductions.…”

Section: Resultsmentioning

confidence: 99%

Reversible Redox Chemistry in Pyrrolidinium‐Based TEMPO Radical and Extended Viologen for High‐Voltage and Long‐Life Aqueous Redox Flow Batteries

Pan

Gao

Liang

et al. 2022

Advanced Energy Materials

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excellent stability can provide a good choice to meet this demand. [2][3][4][5] However, the extensively studied all-vanadium RFBs suffer some long-standing problems, such as the high costs of cation exchange membranes and vanadium-based active materials and the electrolyte crossover and corrosion issues in strong acidic conditions. [6] Aqueous organic redox flow batteries (AORFBs), after being reported, [7,8] received particular attention among the existing flow battery technologies, primarily because organic redox-active materials possess numerous advantages including great natural abundance, facile structural tailorability, tunable electrochemical properties, and potentially low costs. The solutions of a number of organic active molecules, such as viologen, anthraquinone, phenazine, and azobenzene derivatives, have been investigated as the anolytes for AORFBs. And a few organic molecules are available for the catholytes, typically, 2,2,6,6-tetramethyl piperidin-1-yl)oxyl (TEMPO) and metallocene derivatives. [17][18][19][20][21][22][23][24][25][26][27][28][29][30][31][32] Considering the high redox potential of TEMPO and its derivatives (ranged from 0.8 to 1.0 V versus standard hydrogen electrode, SHE), the introduction of highly hydrophilic groups, such as the quaternary ammonium group, is a promising approach to further improve the energy density. [20,23] However, up to date, the capacity degradation mechanism on the TEMPO/viologen systems remains unclear, and a lack of appropriate spectroscopic methods was established to study the electrochemical reversibility of redox-active organic species, especially in radical involved systems.Given that the chemically stable pyrrolidinium group has an ultrawide electrochemical window and strong polarity, it has been frequently utilized as a cationic moiety of ionic liquids. [33,34] When coupled with Clion, the pyrrolidinium functionalized organic species also appear to be highly watersoluble. Herein, we report the successful synthesis of pyrrolidinium cation functionalized TEMPO and extended viologen (Pyr-TEMPO and [PyrPV]Cl 4 ), which can serve as a highlysoluble organic redox pair with high cell voltage and excellent redox reversibility in AORFBs (Figure 1). The introduction Aqueous organic redox flow batteries (AORFBs) are regarded as a promising candidate for grid-scale, low-cost and sustainable energy storage. However, their performance is restricted by low aqueous solubility and the narrow potential gap of the organic redox-active species. Herein, a highly-soluble organic redox pair based on pyrrolidinium cation functionalized TEMPO and extended viologen, namely Pyr-TEMPO and [PyrPV]Cl 4 , which exhibits high cell voltage (1.57 V) and long cycling life (over 1000 cycles) in AORFBs is reported. The intrinsic hydrophilic nature of the pyrrolidinium group enables high aqueous solubilities (over 3.35 m for Pyr-TEMPO and 1.13 m for [PyrPV]Cl 4 ). Furthermore, the interaction of nitroxyl radicals with water is observed, which may be helpful to prevent collision-induced...

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“…Briefly, 1,4‐di‐(pyridin‐4‐yl)benzene (PhPy) was reacted with diethyl(3‐bromopropyl)phosphonate in acetonitrile at 95 °C for 48 h, followed by a simple hydrolysis of the ester resulting in the desired product in 77 % overall yield. The PhPy precursor can be synthesized economically by a single‐step Suzuki–Miyaura reaction of 1,4‐dibromobenzene and 4‐pyridineboronic acid pinacol ester with a very high yield (>90 %) [18] . PSS‐TEMPO was made in a single step by using the commercially available 4‐hydroxy TEMPO.…”

Section: Resultsmentioning

confidence: 99%

High‐Power Near‐Neutral Aqueous All Organic Redox Flow Battery Enabled with a Pair of Anionic Redox Species

et al. 2022

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Aqueous organic redox flow batteries (AORFBs) are regarded as a promising alternative for low-cost and durable grid-scale energy storage. However, the narrow potential gap, chemical lability and membrane fouling in most AORFBs constitute formidable roadblocks for practical applications. Herein, a pair of anionic organic molecules, namely (PPBPy)Br 2 and PSS-TEMPO, are proposed. The (PPBPy)Br 2 in anolyte reveals remarkable electrochemical stability without degradation after 1000 cycles, while PSS-TEMPO in catholyte presents a capacity decay rate as low as 0.012 %/cycle. At near-neutral conditions, the (PPBPy)Br 2 /PSS-TEMPO flow cell exhibits a high voltage of 1.61 V, extremely low permeability across cation-exchange membrane and thus excellent cycling stability. Notably, a highest peak power density of 509 mW cm À 2 has been achieved among reported allorganic aqueous RFBs. The molecular engineering strategies demonstrated here could provide a credible example of high-performance AORFBs.

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The Dual Role of Bridging Phenylene in an Extended Bipyridine System for High-Voltage and Stable Two-Electron Storage in Redox Flow Batteries

Cited by 42 publications

References 57 publications

Constructing Self‐Adapting Electrostatic Interface on Lithium Metal Anode for Stable 400 Wh kg⁻¹ Pouch Cells

Constructing Self‐Adapting Electrostatic Interface on Lithium Metal Anode for Stable 400 Wh kg⁻¹ Pouch Cells

Reversible Redox Chemistry in Pyrrolidinium‐Based TEMPO Radical and Extended Viologen for High‐Voltage and Long‐Life Aqueous Redox Flow Batteries

High‐Power Near‐Neutral Aqueous All Organic Redox Flow Battery Enabled with a Pair of Anionic Redox Species

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The Dual Role of Bridging Phenylene in an Extended Bipyridine System for High-Voltage and Stable Two-Electron Storage in Redox Flow Batteries

Cited by 42 publications

References 57 publications

Constructing Self‐Adapting Electrostatic Interface on Lithium Metal Anode for Stable 400 Wh kg−1 Pouch Cells

Constructing Self‐Adapting Electrostatic Interface on Lithium Metal Anode for Stable 400 Wh kg−1 Pouch Cells

Reversible Redox Chemistry in Pyrrolidinium‐Based TEMPO Radical and Extended Viologen for High‐Voltage and Long‐Life Aqueous Redox Flow Batteries

High‐Power Near‐Neutral Aqueous All Organic Redox Flow Battery Enabled with a Pair of Anionic Redox Species

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Constructing Self‐Adapting Electrostatic Interface on Lithium Metal Anode for Stable 400 Wh kg⁻¹ Pouch Cells

Constructing Self‐Adapting Electrostatic Interface on Lithium Metal Anode for Stable 400 Wh kg⁻¹ Pouch Cells