Quartz Crystal Impedance Response of Nonhomogenous Composite Electrodes in Contact with Liquids

Daikhin, Leonid; Sigalov, Sergey; Levi, Mikhael D.; Salitra, Gregory; Aurbach, Doron

doi:10.1021/ac202410q

Cited by 27 publications

(60 citation statements)

References 27 publications

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“…calculated for the experiment related to Figure 3 was 9.39. Based on parallel studies of complex electrochemical processes by EQCM, [21][22][23] we can attribute such a discrepancy to viscoelastic effects that limit the simple applicability of the Sauerbrey equation 24 for these measurements. All our tests with MgTFSI 2 /MgCl 2 solutions showed that during prolonged electrochemical measurements, an un-identified by-product was formed (and at least part of it precipitated on the electrode surface), a by-product which is associated with the passage of faradaic currents.…”

Section: Resultsmentioning

confidence: 99%

Evaluation of (CF₃SO₂)₂N⁻(TFSI) Based Electrolyte Solutions for Mg Batteries

Shterenberg

Salama

Yoo

et al. 2015

J. Electrochem. Soc.

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328

445

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MgTFSI 2 is the only ether-soluble "simple" magnesium salt. The poor electrochemical performance of Mg electrodes in its solutions hinders its practicality as a viable electrolyte for Mg batteries. MgTFSI 2 /DME solutions were demonstrated to dissolve large quantities of MgCl 2 and produce electrolyte solutions with superior performance, though the electrochemical performance, mainly in terms of reversibility, of MgTFSI 2 /MgCl 2 (DME) solutions cannot yet compete with that of organometallic based electrolyte solutions. We believe that the solutions' purity level governs the overall electrochemical performance, especially in solutions where a strong reductant (i.e Grignard reagent) is not present to act as an impurity scavenger. In this work, we alter the performance of the MgTFSI 2 /MgCl 2 (DME) solutions through chemical and electrochemical conditioning and demonstrate the effect on the solutions' electrochemical characteristics. We demonstrate relatively high reversible behavior of Mg deposition/dissolution with crystalline uniformity of the Mg deposits, complemented by a fully reversible intercalation/de-intercalation process of Mg ions into Mo 6 S 8 cathodes. We also investigated LiTFSI/MgCl 2 solutions which exhibited even higher reversibility than MgTFSI 2 /MgCl 2 (DME) solutions, which we attribute to the higher purity level available for the LiTFSI salt. Magnesium is a natural candidate anode material for "next generation" rechargeable batteries due to its high volumetric capacity (3833 mAh/cm 3 ), low reduction potential (−2.3 V) wide abundance, and low price.1 Rechargeable Mg battery research had been developing very slowly since the 1920's but had recently gained a big momentum. Magnesium battery systems will have great difficulties to outperform lithium systems In terms of energy and power density. However, they possess several properties that make them desirable, as they are expected to benefit from a cheaper price and lower hazard levels. One of the core issues developing rechargeable magnesium batteries is the formulation of electrolytic solutions that support reversible magnesium deposition. Other properties such as sufficient ionic conductivity, adequate magnesium ion concentration, and a wide electrochemical window are also mandatory. 15 years ago we synthesized electrolyte solutions that possessed most of the key features listed above. These electrolyte solutions were the product of a Lewis acid/base reaction in which R 2 Mg moieties such as Bu 2 Mg served as the base component, and RAlCl 2 species such as EtAlCl 2 served as the acid component.Hence, we could demonstrate a family of organometallic electrolyte solutions for rechargeable Mg batteries known as di-chloro complex solutions (DCC).2,3 Unfortunately, even the best DCC electrolyte solution does not possess the minimum requirement needed for next generation rechargeable magnesium batteries, e.g. wide electrochemical stability window (>2.2 V), chemical stability and safety. The use of aromatic ligands enabled to develop electrolyte solu...

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Section: Resultsmentioning

confidence: 99%

Evaluation of (CF₃SO₂)₂N⁻(TFSI) Based Electrolyte Solutions for Mg Batteries

Shterenberg

Salama

Yoo

et al. 2015

J. Electrochem. Soc.

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328

445

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“…As a consequence, due to clamping of the electrode particles, the mechanical deformation of the entire composite electrode layer becomes essentially non-uniform. [ 9 ] The description of the complicated solid-liquid interactions originating from variations in the effective electrode layer thickness, h , and its permeability length, ξ , upon ion insertion/ extraction is part of the hydrodynamic admittance problem [ 11,12 ] and is dealt with herein. Figure 2 summarizes the basic electroanalytical features of thin composite Ti 3 C 2 T x electrode coatings (active mass ≈ 60 µg cm -2 ) on a QC surface.…”

Section: Morphology and Electroanalytical Features Of 2d Ti 3 C 2 T Xmentioning

confidence: 99%

Solving the Capacitive Paradox of 2D MXene using Electrochemical Quartz‐Crystal Admittance and In Situ Electronic Conductance Measurements

Levi

Lukatskaya

Sigalov

et al. 2014

Advanced Energy Materials

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Fast ion adsorption processes in supercapacitors enable quick storage/ delivery of signifi cant amounts of energy, while ion intercalation in battery materials leads to even larger amounts of energy stored, but at substantially lower rates due to diffusional limitations. Intercalation of ions into the recently discovered 2D Ti 3 C 2 T x (MXene) occurs with a very high rate and leads to high capacitance, posing a paradox. Herein, by characterizing the mechanical deformations of MXene electrode materials at various states-ofcharge with a variety of cations (Li, Na, K, Cs, Mg, Ca, Ba, and three tetraalkylammonium cations) during cycling by electrochemical quartz-crystal admittance (EQCA, quartz-crystal microbalance with dissipation monitoring) combined with in situ electronic conductance and electrochemical impedance, light is shone on this paradox. Based on this work, it appears that the capacitive paradox stems from cationic insertion, accompanied by signifi cant deformation of the MXene particles, that occurs so rapidly so as to resemble 2D ion adsorption at solid-liquid interfaces. The latter is greatly facilitated by the presence of water molecules between the MXene sheets.

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“…[10] Less known is that any QCM instrument recording both shifts in resonance frequency(F)and resonance width (W,ordissipation factor D = W/F)can be employed as asensitive probe of the potential-induced deformations of composite electrode coatings. [7,8,11] Thee lectrode particles deformations (i.e., achange in their shape and size) modify their hydrodynamic interactions with the contacting liquid, thereby directly affecting experimentally measured values of shifts in F and W. [7,8,11] In contrast to conventional mechanical measurements, [12] deformation of the polymeric binders in composite electrodes is caused by contracting/expanding intercalation particles rather than by applied external force.Y et, non-uniform binder distribution at the particle surface affects the character of the particles deformation. Thed eformation depends on the polymer and the solution nature (e.g., through the polymers elastic modulus), and is also af unction of the electrodes charging rates since the polymers elastic moduli are time (frequency)-dependent through av ariety of relaxation mechanisms.…”

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confidence: 99%

“…[14] Gel formation is further enhanced when at hin layer of NaCMC is strongly held by the intercalation particles after complete drying of the electrode at elevated temperature.S welling of the elastomeric network in aqueous solution facilitates aq uasi-uniform deformation of LiFePO 4 particles:the effective thickness of the porous electrodes layer decreases because the intercalation particles contract during Li-ions extraction, ensuring ad ecrease in DW due to reduction of solid-liquid hydrodynamic interactions. [7,11] In contrast, NaCMC remains completely rigid in aprotic solutions. [2] Figure 3C directly confirms this conclusion:the non-uniform deformation of the electrode'sa ctive mass (resulting in the increase of the dissipation factor) arises as ac onsequence of the non-uniform distribution of the rigid polymeric binder.…”

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confidence: 99%

Non‐Invasive In Situ Dynamic Monitoring of Elastic Properties of Composite Battery Electrodes by EQCM‐D

et al. 2015

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Reversible Li-ion intercalation into composite Li-ion battery (LIB) electrodes is often accompanied by significant dimensional electrode changes (deformation) resulting in significant deterioration of the cycling performance. Viscoelastic properties of polymeric binders affected by intercalation-induced deformation of composite LIB electrodes have never been probed in situ on operating electrochemical cells. Here, we introduce a newly developed noninvasive method, namely electrochemical quartz-crystal microbalance with dissipation monitoring (EQCM-D), for in situ monitoring of elastic properties of polymeric binders during charging of LIB electrodes. As such, we find EQCM-D as a uniquely suitable tool to track the binder's structural rigidity/softness in composite Li insertion electrodes in real-time by the characteristic increase/decrease of the dissipation factor during the charging-discharging process. The binders partially swollen in aprotic solutions demonstrate intermediate viscoelastic charge-rate-dependent behavior, revealing rigid/soft behavior at high/low charging rates, respectively. The method can be adjusted for continuous monitoring of elastic properties of the polymeric binders over the entire LIB electrodes cycling life.

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Quartz Crystal Impedance Response of Nonhomogenous Composite Electrodes in Contact with Liquids

Cited by 27 publications

References 27 publications

Evaluation of (CF₃SO₂)₂N⁻(TFSI) Based Electrolyte Solutions for Mg Batteries

Evaluation of (CF₃SO₂)₂N⁻(TFSI) Based Electrolyte Solutions for Mg Batteries

Solving the Capacitive Paradox of 2D MXene using Electrochemical Quartz‐Crystal Admittance and In Situ Electronic Conductance Measurements

Non‐Invasive In Situ Dynamic Monitoring of Elastic Properties of Composite Battery Electrodes by EQCM‐D

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Quartz Crystal Impedance Response of Nonhomogenous Composite Electrodes in Contact with Liquids

Cited by 27 publications

References 27 publications

Evaluation of (CF3SO2)2N−(TFSI) Based Electrolyte Solutions for Mg Batteries

Evaluation of (CF3SO2)2N−(TFSI) Based Electrolyte Solutions for Mg Batteries

Solving the Capacitive Paradox of 2D MXene using Electrochemical Quartz‐Crystal Admittance and In Situ Electronic Conductance Measurements

Non‐Invasive In Situ Dynamic Monitoring of Elastic Properties of Composite Battery Electrodes by EQCM‐D

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Evaluation of (CF₃SO₂)₂N⁻(TFSI) Based Electrolyte Solutions for Mg Batteries

Evaluation of (CF₃SO₂)₂N⁻(TFSI) Based Electrolyte Solutions for Mg Batteries