Liquid Metal Electrodes for Energy Storage Batteries

Li, Haomiao; Yin, Huayi; Wang, Kangli; Cheng, Shijie; Jiang, Kai; Sadoway, Donald R.

doi:10.1002/aenm.201600483

Cited by 154 publications

(95 citation statements)

References 103 publications

(211 reference statements)

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“…The discharge capacities of N‐MnO 2– x @TiC/C at 0.2, 0.5, 1.0, 2.0, and 3 A g −1 are measured to be 286.3, 241.3, 204, 155.2, and 121.5 mAh g −1 (Figure S9a, Supporting Information), respectively, higher than the MnO 2 @TiC/C and N‐(MnO 2 /Mn 3 O 4 )@TiC/C samples (Figures S9b and S8c, Supporting Information) and substantially superior to most of the reported ZIB cathodes (Table S3, Supporting Information). In addition to the much better rate performance, the N‐MnO 2– x @TiC/C cathode is also demonstrated with a higher energy density of 386.5 Wh kg −1 at 270 W kg −1 and 164 Wh kg −1 at high power energy density of 4050 W kg −1 (Figure S10, Supporting Information), which outperform the other reported cathodes, such as δ‐MnO 2 (320 Wh kg −1 at 106.24 W kg −1 ), todorokite‐type MnO 2 (150 Wh kg −1 at 170 W kg −1 ), VS 2 (123 Wh kg −1 at 32.3 W kg −1 ), V 2 O 5 (237.16 Wh kg −1 at 49 W kg −1 ), ZnMn 2 O 4 (202 Wh kg −1 at 67.5 W kg −1 ), H 2 V 3 O 8 (250 Wh kg −1 at 62.5 W kg −1 ), V 2 O 5 @PEDOT/CC (243.3 Wh kg −1 at 90 W kg −1 ), MoS 2 (148.2 Wh kg −1 at 70.5 W kg −1 ), and Na 3 V 2 (PO 4 ) 2 F 3 (148.2 Wh kg −1 at 70.5 W kg −1 ) . Furthermore, excellent cycling performances is achieved for the N‐MnO 2– x @TiC/C electrode (Figure e).…”

Section: Resultsmentioning

confidence: 90%

Defect Promoted Capacity and Durability of N‐MnO_2–_x Branch Arrays via Low‐Temperature NH₃ Treatment for Advanced Aqueous Zinc Ion Batteries

Zhang

Deng

Luo

et al. 2019

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Defect engineering (doping and vacancy) has emerged as a positive strategy to boost the intrinsic electrochemical reactivity and structural stability of MnO2‐based cathodes of rechargeable aqueous zinc ion batteries (RAZIBs). Currently, there is no report on the nonmetal element doped MnO2 cathode with concomitant oxygen vacancies, because of its low thermal stability with easy phase transformation from MnO2 to Mn3O4 (≥300 °C). Herein, for the first time, novel N‐doped MnO2–x (N‐MnO2–x) branch arrays with abundant oxygen vacancies fabricated by a facile low‐temperature (200 °C) NH3 treatment technology are reported. Meanwhile, to further enhance the high‐rate capability, highly conductive TiC/C nanorods are used as the core support for a N‐MnO2–x branch, forming high‐quality N‐MnO2–x@TiC/C core/branch arrays. The introduced N dopants and oxygen vacancies in MnO2 are demonstrated by synchrotron radiation technology. By virtue of an integrated conductive framework, enhanced electron density, and increased surface capacitive contribution, the designed N‐MnO2–x@TiC/C arrays are endowed with faster reaction kinetics, higher capacity (285 mAh g−1 at 0.2 A g−1) and better long‐term cycles (85.7% retention after 1000 cycles at 1 A g−1) than other MnO2‐based counterparts (55.6%). The low‐temperature defect engineering sheds light on construction of advanced cathodes for aqueous RAZIBs.

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Section: Resultsmentioning

confidence: 90%

Defect Promoted Capacity and Durability of N‐MnO_2–_x Branch Arrays via Low‐Temperature NH₃ Treatment for Advanced Aqueous Zinc Ion Batteries

Zhang

Deng

Luo

et al. 2019

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175

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“…8(a). The values of the diffusion coefficients obtained at various applied potentials can be determined by using Cottrell's equation as shown in equation (4). Fig.…”

Section: Resultsmentioning

confidence: 99%

“…These liquid layers float over each other because of differences in their density and immiscibility. The all-liquid battery construction confers advantages of extremely high current density, long cycle life, and simple manufacture of large-scale storage systems [3,4]. The Sadoway research group has developed several liquid metal batteries, such as Mg//Mg-Sb [5], Li//Sb-Pb [6], Li//SbSn [7], calcium-based [8], and sodium-based liquid metal battery [9].…”

Section: Introductionmentioning

confidence: 99%

Electrode Behaviors of Na-Zn Liquid Metal Battery

Martínez

Osen

et al. 2017

J. Electrochem. Soc.

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The electroreduction processes on a Mo electrode in a Na-Zn liquid metal battery cell with a molten NaCl-CaCl2-ZnCl2 electrolyte were investigated at 565 °C. The effect of the battery operating parameters on the loss rate of Na was determined by using electrochemical techniques. The results indicated that the chemical reaction of the reduced Ca and Na with ZnCl2 takes place very quickly, and the electroreduction of Na. Volatilization is mainly responsible for the loss of Na, and a high current density during charging led to the severe competitive deposition of Zn with Na.

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“…Moreover, the absence of solid electrodes endows the battery with an extended service lifetime (>10,000 cycles). 2,3 The negative and positive electrodes are selected based on melting point and density as well as the voltage associated with alloy formation, whereas the electrolyte is chosen based on melting point, metal solubility, density, ionic conductivity, and electrochemical window. 2 Metal solubility in the electrolyte varies exponentially with operating temperature.…”

mentioning

confidence: 99%

Communication—Molten Amide-Hydroxide-Iodide Electrolyte for a Low-Temperature Sodium-Based Liquid Metal Battery

Ashour

Yin

Ouchi

et al. 2017

J. Electrochem. Soc.

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The low cost and high abundance of sodium make it an attractive choice for the negative electrode in a liquid metal battery. However, sodium has not found use in this application owing to the high solubility of the metal in its molten halides which results in poor coulombic efficiency and an unacceptably high rate of self discharge. In this work, we investigated the electrochemical behavior of the ternary eutectic of NaNH 2 , NaOH and NaI (m.p. 127 • C) and evaluated its usefulness as an electrolyte for sodium-based liquid metal batteries. Cyclic voltammetry revealed an electrochemical window of 1.3 V at 180 • C. The anodic limit is set by the oxidation of amide anions to form hydrazine gas. Liquid metal batteries consist of two metals of different electronegativity separated by molten salt. During discharge, the battery operates through alloying an electropositive liquid metal (e.g. Mg, Na, Li, or Ca) in an electronegative metal (e.g. Bi, Pb, Sb, or Zn). The all-liquid design allows the battery to operate at high current densities (1 A/cm 2 ) 1 with low overvoltage due to fast mass transport in the liquid state and high ionic conductivity of molten salts. Moreover, the absence of solid electrodes endows the battery with an extended service lifetime (>10,000 cycles). 2,3The negative and positive electrodes are selected based on melting point and density as well as the voltage associated with alloy formation, whereas the electrolyte is chosen based on melting point, metal solubility, density, ionic conductivity, and electrochemical window. 2Metal solubility in the electrolyte varies exponentially with operating temperature. High metal solubility in the electrolyte can influence the performance of liquid metal battery through increasing electronic conductivity, which increases the rate of self-discharge leading to lower coulombic efficiency. A low-melting electrolyte (<200• C) can substantially reduce metal solubility thereby allowing batteries to be built with low-cost negative electrodes (e.g., Na, Ca) that are otherwise inaccessible at higher temperatures (>500• C). Moreover, reducing the operating temperature below 200• C can also reduce the total battery cost through savings associated with cell container, thermal insulation, and wiring.Early work on low-melting sodium-bearing salts focused on mixtures of NaOH, NaI, and NaBr and was driven by their utility for sodium electrowinning. [4][5][6] The thought was that electrolysis at a lower temperature would reduce operating costs and improve process efficiency. More recently, in connection with work on sodium-based liquid metal batteries, Spatocco et al.7 investigated a binary eutectic of NaOH and NaI as an electrolyte operable at intermediate temperature (<280• C). An electrochemical window of 2.4 volts was measured at 250• C. In contact with liquid sodium, significantly lower values of self-discharge current were observed in this melt compared to those in early Na||Bi cells operating at much higher temperatures (necessitated by their higher-melting halide elec...

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Liquid Metal Electrodes for Energy Storage Batteries

Cited by 154 publications

References 103 publications

Defect Promoted Capacity and Durability of N‐MnO_2–_x Branch Arrays via Low‐Temperature NH₃ Treatment for Advanced Aqueous Zinc Ion Batteries

Defect Promoted Capacity and Durability of N‐MnO_2–_x Branch Arrays via Low‐Temperature NH₃ Treatment for Advanced Aqueous Zinc Ion Batteries

Electrode Behaviors of Na-Zn Liquid Metal Battery

Communication—Molten Amide-Hydroxide-Iodide Electrolyte for a Low-Temperature Sodium-Based Liquid Metal Battery

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Liquid Metal Electrodes for Energy Storage Batteries

Cited by 154 publications

References 103 publications

Defect Promoted Capacity and Durability of N‐MnO2–x Branch Arrays via Low‐Temperature NH3 Treatment for Advanced Aqueous Zinc Ion Batteries

Defect Promoted Capacity and Durability of N‐MnO2–x Branch Arrays via Low‐Temperature NH3 Treatment for Advanced Aqueous Zinc Ion Batteries

Electrode Behaviors of Na-Zn Liquid Metal Battery

Communication—Molten Amide-Hydroxide-Iodide Electrolyte for a Low-Temperature Sodium-Based Liquid Metal Battery

Contact Info

Product

Resources

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Defect Promoted Capacity and Durability of N‐MnO_2–_x Branch Arrays via Low‐Temperature NH₃ Treatment for Advanced Aqueous Zinc Ion Batteries

Defect Promoted Capacity and Durability of N‐MnO_2–_x Branch Arrays via Low‐Temperature NH₃ Treatment for Advanced Aqueous Zinc Ion Batteries