Transport Properties of Solid Polymer Electrolytes Prepared from Oligomeric Fluorosulfonimide Lithium Salts Dissolved in High Molecular Weight Poly(ethylene oxide)

Geiculescu, Olt E.; Rajagopal, Rama V.; Creager, Stephen E.; DesMarteau, Darryl D.; Zhang, Xiangwu; Fedkiw, Peter S.

doi:10.1021/jp062648p

Cited by 32 publications

(29 citation statements)

References 38 publications

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“…It is based on the measurement of conductivity by ac impedance, salt diffusion coefficient by restricted diffusion, steady-state current under dc polarization, and the thermodynamic factor using concentration cells. Our approach, based on concentrated solution theory, is very similar to that proposed by Ma et al 33 A majority of t + values reported in the literature [41][42][43][44][45][47][48][49]58,59,61 are based on the steady-state current method pioneered by Bruce and Vincent. 42,57 In a few cases [34][35][36][37] where the approach of Ma et al is used to determine t + , there is no attempt to relate t + values thus obtained with those that might be obtained using the steady-state current method.…”

Section: Discussionmentioning

confidence: 98%

“…It is now fairly routine to report both σ and t +,SS of newly-developed polymer electrolytes. 41,44,45,47,48,[58][59][60] The question of limits on i ss /i 0 , or equivalently, t +,SS is an interesting open question. While most papers have reported i ss /i 0 values between 0 and 1, there is at least one report wherein i ss /i 0 obtained from an electrolyte was greater than 1.…”

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confidence: 99%

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Negative Transference Numbers in Poly(ethylene oxide)-Based Electrolytes

Pesko

Timachova

Bhattacharya

et al. 2017

J. Electrochem. Soc.

185

367

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The performance of battery electrolytes depends on three independent transport properties: ionic conductivity, diffusion coefficient, and transference number. While rigorous experimental techniques for measuring conductivity and diffusion coefficients are well-established, popular techniques for measuring the transference number rely on the assumption of ideal solutions. We employ three independent techniques for measuring transference number, t + , in mixtures of polyethylene oxide (PEO) and lithium bis(trifluoromethanesulfonyl) imide (LiTFSI) salt. Transference numbers obtained using the steady-state current method pioneered by Bruce and Vincent, t +,SS , and those obtained by pulsed-field gradient NMR, t +,NMR , are compared against a new approach detailed by Newman and coworkers, t +,Ne , for a range of salt concentrations. The latter approach is rigorous and based on concentrated solution theory, while the other two approaches only yield the true transference number in ideal solutions. Not surprisingly, we find that t +,SS and t +,NMR are positive throughout the entire salt concentration range, and decrease monotonically with increasing salt concentration. In contrast, t +,Ne has a non-monotonic dependence on salt concentration and is negative in the highly-concentrated regime. Our work implies that ion transport in PEO/LiTFSI electrolytes at high salt concentrations is dominated by the transport of ionic clusters. Energy density and safety of conventional lithium-ion batteries is limited by the use of liquid electrolytes comprising mixtures of flammable organic solvents and lithium salts. Polymer electrolytes have the potential to address both limitations. However, the power and lifetime of batteries containing solvent-free polymer electrolytes remain inadequate for most applications. The performance of electrolytes in batteries depends on three independent transport properties: ionic conductivity, σ, salt diffusion coefficient, D, and cation transference number, t + .1 The poor performance of batteries with polymer electrolytes is generally attributed to low conductivity, which is on the order of 10 −3 S/cm at 90• C for mixtures of polyethylene oxide (PEO) and lithium bis(trifluoromethanesulfonyl) imide (LiTFSI) salt, 2,3 compared to that of liquid electrolytes which is 10 −2 S/cm at ambient temperatures. 4 Much of the literature in this field has been devoted to increasing the ionic conductivity of these materials.5-32 The purpose of our work is to shed light on another transport property of polymer electrolytes, the transference number.In a pioneering study, Ma and coworkers showed that the transference number of a mixture of PEO and a sodium salt is negative. 33Following this approach, others have obtained t + <0 in polymers containing lithium or sodium salts. [34][35][36] Nevertheless, the majority of reports for t + in polymer electrolytes fall between zero and one. [37][38][39][40][41][42][43][44][45][46][47][48][49][50][51] In contrast, all reports of t + in non-aqueous liquid electrolytes containi...

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Section: Discussionmentioning

confidence: 98%

mentioning

confidence: 99%

Negative Transference Numbers in Poly(ethylene oxide)-Based Electrolytes

Pesko

Timachova

Bhattacharya

et al. 2017

J. Electrochem. Soc.

185

367

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“…[15][16][17] However, the practical application of PEO for electrolyte materials is limited due to its low ionic conductivity at room temperature; the ionic conduction occurs mostly in the amorphous phase while PEO is highly crystalline at room temperature. [18][19][20] To decrease the crystallinity or to increase the conductivity by increasing the free volume or the mobility of polymer chains, comb-like or hairy-rod-like polymers and inorganic scaffolds having oligomeric ethylene oxide groups were prepared. 16,[21][22][23][24][25] Especially polysiloxanes having oligo(ethylene oxide) have been extensively studied because they have reasonably high ionic conductivity due to the high mobility of the siloxane backbone, although they are not solid polymer electrolytes.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and properties of polysiloxanes containing polyhedral oligomeric silsesquioxane (POSS) and oligo (ethylene oxide) groups in the side chains

2010

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Comb-like polysiloxanes with polyhedral oligomeric silsesquioxane (POSS) and oligo(ethylene oxide) groups (EO) in the side chains were prepared through the hydrosilylation reaction of poly(ethylhydrosiloxane) (PEHS) with 1-allyl-3,5,7,9,11,13,15-heptacyclopentylpentacyclo-[9.5.1.1 3,9 .1 5,15 .1 7,13 ] octasiloxane (allyl-CyPOSS) and allyl-functionalized oligo(ethylene glycol) monomethyl ethers. The physical and chemical properties of these polysiloxanes were studied systematically by changing the content of bulky POSS groups and hydrophilic flexible oligo(ethylene oxide) groups with different lengths. For example, the glass transition temperature of the polymer increased with increasing content of POSS side groups, whereas the melting temperature and heat of fusion of the oligo(ethylene oxide) side group decreases. Furthermore, the glass transition temperature and melting temperature increase when the length of the EO group was increased, whereas the decomposition temperature decreased.

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“…Diffusion coefficient, also called diffusivity, is an important parameter indicative of the diffusion mobility. The diffusion coefficients of cations and anions of each polymer electrolyte have been calculated from the measured values of conductivity and cation transference number ( t + ), using the following equations

n = N ρ \times molar ratio of salt / molecular weight of the salt

D_{+} = D t_{+}

D = D_{+} + D_{-} = kT σ / n e^{2}

…”

Section: Resultsmentioning

confidence: 98%

Biopolymer agar‐agar doped with NH₄SCN as solid polymer electrolyte for electrochemical cell application

Selvalakshmi¹,

Vijaya²,

Selvasekarapandian

et al. 2017

J of Applied Polymer Sci

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A new polymer electrolyte based on the biopolymer Agar-Agar doped with ammonium thiocyanate (NH 4 SCN) has been prepared and characterized by FTIR analysis, X-ray diffraction measurements, AC impedance spectroscopy, transference number measurements, and DSC analysis. The Fourier transform infrared analysis confirms the complex formation between agar and NH 4 SCN. The amorphous nature of the polymer electrolyte has been revealed from X-ray diffraction analysis. The highest ionic conductivity has been observed for the sample of composition 1:1 between Agar and NH 4 SCN. As a function of temperature, the ionic conductivity of this sample exhibits Arrhenius behavior increasing from 1.03 3 10 23 S cm 21 at ambient temperature to 3.16 3 10 23 S cm 21 at 343 K. The transference number has been estimated by the dc polarization method, and it has been proven that the conducting species are predominantly cations. Using the highest conductivity polymer electrolyte, solid state electrochemical cell has been fabricated and cell parameters are reported.

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Transport Properties of Solid Polymer Electrolytes Prepared from Oligomeric Fluorosulfonimide Lithium Salts Dissolved in High Molecular Weight Poly(ethylene oxide)

Cited by 32 publications

References 38 publications

Negative Transference Numbers in Poly(ethylene oxide)-Based Electrolytes

Negative Transference Numbers in Poly(ethylene oxide)-Based Electrolytes

Synthesis and properties of polysiloxanes containing polyhedral oligomeric silsesquioxane (POSS) and oligo (ethylene oxide) groups in the side chains

Biopolymer agar‐agar doped with NH₄SCN as solid polymer electrolyte for electrochemical cell application

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Transport Properties of Solid Polymer Electrolytes Prepared from Oligomeric Fluorosulfonimide Lithium Salts Dissolved in High Molecular Weight Poly(ethylene oxide)

Cited by 32 publications

References 38 publications

Negative Transference Numbers in Poly(ethylene oxide)-Based Electrolytes

Negative Transference Numbers in Poly(ethylene oxide)-Based Electrolytes

Synthesis and properties of polysiloxanes containing polyhedral oligomeric silsesquioxane (POSS) and oligo (ethylene oxide) groups in the side chains

Biopolymer agar‐agar doped with NH4SCN as solid polymer electrolyte for electrochemical cell application

Contact Info

Product

Resources

About

Biopolymer agar‐agar doped with NH₄SCN as solid polymer electrolyte for electrochemical cell application