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Study of the Segmental Dynamics and Ion Transport of Solid Polymer Electrolytes in the Semi-crystalline State

Chen, Xi Chelsea ; Sacci, Robert L. ; Osti, Naresh C. ; [et al.]

Frontiers Media SA ; 2021

In: Frontiers in Chemistry Vol. 8 ( 2021-1-13)

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In: Frontiers in Chemistry, Frontiers Media SA, Vol. 8 ( 2021-1-13)

Abstract: Solid polymer electrolytes are promising in fulfilling the requirements for a stable lithium metal anode toward higher energy and power densities. In this work, we investigate the segmental dynamics, ionic conductivity, and crystallinity of a polymer electrolyte consisting of poly(ethylene oxide) (PEO) and lithium triflate salt, in the semi-crystalline state. Using quasi-elastic neutron scattering, the segmental dynamics of PEO chains confined between the crystalline lamellae is quantified, using Cole–Cole analysis. We show that the structural relaxation time, τ 0 , of PEO equilibrated near room temperature is six-fold longer than the same sample that had just cooled down to room temperature. This corresponds to a three-fold smaller ionic conductivity in the equilibrated condition. This work reveals that the segmental dynamics of semi-crystalline polymer electrolytes is very sensitive to thermal history. We demonstrate that quasi-elastic neutron scattering can be used to characterize the ion transport and segmental dynamics in the semi-crystalline state.

Type of Medium: Online Resource

ISSN: 2296-2646

URL: Article

DOI: 10.3389/fchem.2020.592604

Language: Unknown

Publisher: Frontiers Media SA

Publication Date: 2021

detail.hit.zdb_id: 2711776-5

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Ion Dynamics and Electrosorption in Carbon Electrodes with Bimodal Porosities and Heterogeneous Interfaces

Dyatkin, Boris ; Zhang, Yu ; Osti, Naresh C. ; [et al.]

The Electrochemical Society ; 2017

In: ECS Meeting Abstracts Vol. MA2017-02, No. 8 ( 2017-09-01), p. 638-638

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2017-02, No. 8 ( 2017-09-01), p. 638-638

Abstract: Electrochemical capacitors offer high reliabilities and power densities and demonstrate exceptional promise in a broad range of energy storage and management applications. However, research efforts have not, to date, properly explored the influence of electrode interfaces’ heterogeneity and disorder on charge storage and dynamics of electrosorbed ions. Surface functional groups and structural carbon defects contribute quantum capacitance.[1] Specific surface functional groups, which must appropriately match the chemistries of electrosorbed ions, develop favorable interfaces that reduce impedance and improve cyclabilities.[2] Finally, ionophilic surfaces draw ions away from pore surfaces and improve electrosorption during charge and discharge processes.[3] However, these effects strongly depend on electrode pore dimensions and behaviors of ions in confinement. Furthermore, standard materials characterization and electrochemical testing techniques cannot properly assess interactions at electrode/electrolyte interfaces. Subsequently, in-depth studies must rely on combinations of well-tailored experimental model systems, in-depth X-ray and neutron scattering techniques, and computational modeling to assess the influences of disordered interfaces on capacitance. Our research investigated the effect of electrode surface heterogeneity and disorder in complex pore architectures and electrolytes with large, non-idealized electrolytes. The approach used carbide-derived carbons (CDCs) synthesized from a Mo 2 C precursor at 800 °C. This electrode material offered bimodal pore size distributions (0.8 nm and 2.6 nm diameter pores, shown in Figure 1a), and 1300 °C vacuum annealing or 400 °C air oxidation yielded, respectively, defunctionalized or oxidized pore surfaces. We filled these pores with 1-octyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ([OMIm + ][TFSI - ]) room-temperature ionic liquid (RTIL). QENS measurements on these systems determined that the ions were significantly more mobile in oxidized pores than in defunctionalized pores (Figure 1b). A Cole-Cole model derived mobility information, and the RTIL diffusion coefficient in oxidized pores (2.71*10 -10 m 2 s -1 ) was more than twice as large as the one for the same RTIL in defunctionalized pores (1.05*10 -10 m 2 s -1 ) due to lower ion densities in oxidized pores. Electrochemical impedance analysis showed that electrochemically driven ionic mobility was higher in oxidized pores. On the other hand, defunctionalized pores demonstrated contained higher ion densities, and, subsequently, featured higher charge storage densities (Figure 3f). However, cyclic voltammograms suggested charge saturation and pore de-filling behaviors at low potentials; surface chemistry influenced the magnitude of this effect. Molecular dynamic (MD) simulations showed similar strong affinities of oxidized surfaces for RTIL ions, which lowered their charge storage densities in 2.6 nm diameter pores. X-ray Pair Distribution Function (PDF) analysis showed differences in ion-ion correlations between bulk and confined states and further underscored the influence of pore and ion diameter on electrode/electrolyte interactions at heterogeneous interfaces. [1] Dyatkin, B. & Gogotsi, Y. Effects of Structural Disorder and Surface Chemistry on Electric Conductivity and Capacitance of Porous Carbon Electrodes. Faraday Discussions 172, 139-162, (2014). [2] Dyatkin, B., et al . Capacitance, Charge Dynamics, and Electrolyte-Surface Interactions in Functionalized Carbide-Derived Carbon Electrodes. Progress in Natural Science - Materials International 25, 631–641, (2015). [3] Dyatkin, B., et al . Influence of Surface Oxidation on Ion Dynamics and Capacitance in Porous and Non-Porous Carbon Electrodes. The Journal of Physical Chemistry C , (2016). Figure 1

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2017-02/8/638

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2017

detail.hit.zdb_id: 2438749-6

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Maximizing ion dynamics and electrochemical performance of ionic liquid-acetonitrile electrolyte in Ti 3 C 2 T x MXene

Osti, Naresh C ; Lin, Xiaobo ; Zhao, Wei ; [et al.]

IOP Publishing ; 2023

In: 2D Materials Vol. 10, No. 1 ( 2023-01-01), p. 014014-

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In: 2D Materials, IOP Publishing, Vol. 10, No. 1 ( 2023-01-01), p. 014014-

Abstract: Modification of the structure and morphology of MXene electrodes and the formulation of the electrolytes used in their supercapacitor configurations are significant factors affecting the performance of electrochemical devices. In this study, we investigated the electrochemical performance and ion dynamics of 1-ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide, [EmimTFSI], ionic liquid in the presence of acetonitrile (ACN) at different concentrations in Ti 3 C 2 T x MXene supercapacitor. We found an optimum concentration of ACN, at which more cations from the ionic liquid attach to the MXene electrode surface, providing higher electrochemical performance. This higher capacitance is also associated with increased microscopic dynamics of the cation away from the pore wall. These findings give a guideline to optimize the performance of MXene-based supercapacitors using organic solvents-ionic liquid-based electrolyte systems.

Type of Medium: Online Resource

ISSN: 2053-1583

URL: Article

DOI: 10.1088/2053-1583/acacac

Language: Unknown

Publisher: IOP Publishing

Publication Date: 2023

detail.hit.zdb_id: 2779376-X

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(Invited) Understanding the Dynamics of Confined Species in Electrochemical Energy Storage Materials

Bridges, Craig A. ; Osti, Naresh C. ; Martins, Murillo L. ; [et al.]

The Electrochemical Society ; 2020

In: ECS Meeting Abstracts Vol. MA2020-01, No. 1 ( 2020-05-01), p. 52-52

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2020-01, No. 1 ( 2020-05-01), p. 52-52

Abstract: Layered structures have played an important role in the development of electrochemical energy storage, for the relative ease of ion motion through two-dimensional diffusion channels, and for the stability of the host structure during battery operation. There have been several recent examples in which the performance of ion conducting materials has been improved through the presence of confined species between the layers, potentially through increasing the stability of the layers or enhancing the diffusion of ions. This may be observed for both electrode and electrolyte materials and is exemplified by the recent alternative to ionic liquid (IL) electrolytes, called conductive “solid-like” electrolytes, or the quasi-solid liquid electrolyte (QSLE). In the QSLE based upon boron nitride, ionic liquid electrolyte is confined within the BN layers. The electrolyte is intended to take the higher conductivity advantage of liquid electrolytes and combine this with the superior mechanical stability of BN based solid electrolytes. This hybrid solid electrolyte is derived from few layer nanoporous BN powders; the powders exhibit high surface area ( 〉 800 m 2 /g) with layers and micropores ( 〈 2 nm) for the infiltration of IL. X-ray diffraction indicates that the broad peak associated with the inter-layer separation shifts to longer d-spacing with absorption and confinement of IL. These infiltrated powders are then pressed to form a mechanically stable electrolyte, with high ionic conductivity. Such electrolytes can show robust stability against dendrite formation during battery cycling, which is a key issue in battery safety. While the properties look promising, there has been little fundamental effort to understand the nature of conduction in these solid-like electrolytes. The dynamics of the IL are expected to play a role in the diffusive motion of Na + /Li + cations dissolved within the hybrid electrolyte. Prior work on confinement of ionic liquids using quasi-elastic neutron scattering (QENS), such as in the pores of a mesoporous carbon, have shown that the dynamics of the IL may not follow expected trends. For example, the translational motion of the IL may increase with confinement, and then slow down as the temperature is increased. Here we will present the effect of confinement on the dynamics of ionic liquid in 11 BN layers using the BASIS spectrometer, and discuss this in relation to other confined electrochemical energy storage systems.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2020-01152mtgabs

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2020

detail.hit.zdb_id: 2438749-6

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