Impact of shape (nanofiller vs. nanorod) of TiO<sub>2</sub> nanoparticle on free‐standing solid polymeric separator for energy storage/conversion devices

Arya, Anil; Saykar, Nilesh G; Sharma, Annu

doi:10.1002/app.47361

Cited by 38 publications

(13 citation statements)

References 92 publications

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“…A survey of literature confirms that for the lithium-ion conducting SPE materials, the LiClO 4 is one of the appealing ionic dopants used enormously for the preparation of SPEs [10,23,27,33,36]. The investigations on numerous NSPE materials have claimed that the dispersion of TiO 2 nanoparticles mostly increases the ionic conductivity, and some studies also reported an unexpected increase by a few orders of magnitude [22,23,30,[49][50][51][52][53][54][55][56][57][58][59][60][61][62]. Some studies have concluded that only the acidic groups surface-modified TiO 2 and some other inorganic nanofillers are effective in increasing the conductivity of the NSPE materials [63,64].…”

Section: Introductionmentioning

confidence: 88%

Dielectric polarization and relaxation processes of the lithium-ion conducting PEO/PVDF blend matrix-based electrolytes: effect of TiO2 nanofiller

Dhatarwal

Sengwa

2020

SN Appl. Sci.

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The effect of TiO 2 nanofiller concentration on the dielectric polarization and relaxation processes of (75PEO/25PVDF)/25 wt% LiClO 4-x wt% TiO 2 (x = 0, 2, 5, 10, 15, and 20) compositions based nanocomposite solid polymer electrolyte (NSPE) films has been investigated by employing the dielectric relaxation spectroscopy. The SEM micrographs demonstrate that the dispersion of TiO 2 nanoparticles enormously alters the spherulitic morphology with the development of some cracks, pores, and wrinkles of these solution-cast prepared NSPE films. The X-ray diffraction study confirms that the heterostructures of these NSPE materials are semicrystalline and their degree of crystallinity increases irregularly with the increase of TiO 2 concentration, however the crystallinity of host polymer blend matrix of these electrolytes decreases. The complex dielectric permittivity spectra of these NSPE materials in the frequency range from 20 Hz to 1 MHz at 27 °C reveal that there is a dominant contribution of electrode polarization and interfacial polarization at lower frequencies, whereas the high frequency permittivity values attribute to dipolar and ionic polarizations. Four types of relaxation processes have been probed by the 'master curve representation' of the dielectric and electrical spectra of these solid ion-dipole complexes. It is observed that the addition of TiO 2 nanoparticles up to 10 wt% in these electrolytes influences the dielectric properties anomalously, but a huge decrease in the dielectric polarization and increase in the relaxation times are noted resulting in a significant decrease in the ionic conductivity of the film at 20 wt% TiO 2 concentration. The dependence of dc ionic conductivity of these lithium-ion conducting NSPE materials on the chain segmental relaxation time and also the degree of crystallinity has been explored. The results of these NSPE materials have also been compared with the TiO 2 nanoparticles loaded different polymer matrices and salts based electrolytes and discussed appropriately. These lithium-ion based electrolyte films are accredited for the solid-state ion-conducting energy storing devices from their electrochemical parameters characterized by LSV, CV, and CA techniques.

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Section: Introductionmentioning

confidence: 88%

Dielectric polarization and relaxation processes of the lithium-ion conducting PEO/PVDF blend matrix-based electrolytes: effect of TiO2 nanofiller

Dhatarwal

Sengwa

2020

SN Appl. Sci.

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“…The crystallite size also known as coherent length is tabulated in Table 2 and we can observe that the values of τ are decreased upon inclusion the nanofillers in both systems. This indicates that the degree of crystallinity of two broad humps has decreased, implying an amorphous phase in the CGPE systems that provide more free volume for the transportation of ions via interaction of nanofiller‐polymer and ion‐polymer 39–41 . In addition, the crystallinity index of the CGPE can be calculated from the ratio of the integrated area of all crystalline peaks to the total integrated area under the XRD peaks using Equation () as follows:

% Crystallinity = \frac{I_{c}}{I_{c} + I_{a}} \times 100,

where, I a and I c are the integrated intensities corresponding to the amorphous and crystalline phases obtained from the area under the curve of XRD graph using OriginPro, respectively.…”

Section: Resultsmentioning

confidence: 99%

Comparison effect of thin microrod‐nanowhisker manganese oxide (MnO₂) and spherical grain‐like cobalt oxide (Co₃O₄) as nanofiller for performance‐enhanced composite gel terpolymer electrolyte‐based dye‐sensitized solar cells

Razali

Goh

Farhana

et al. 2022

J of Applied Polymer Sci

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Gel polymer electrolyte (GPE) are better replacement of liquid electrolyte for dye‐sensitized solar cell (DSSC) but they have low efficiency due to insufficient segmental motion within the electrolyte. By incorporating transition metal oxide nanofiller, it can improve the performance of DSSC due to the existence of cross‐linking center that provides interaction with polymer side chain and redox mediator. Two different transition metal oxides (namely, manganese oxide, MnO2 and cobalt oxide, Co3O4) were synthesized using sonochemical method and incorporated as nanofiller. Poly (vinyl butyral‐co‐vinyl alcohol‐co‐vinyl acetate) (P(VB‐co‐VA‐co‐VAc)) as a host terpolymer and sodium iodide (NaI) as a dopant salt were used to formulate the composite gel terpolymer electrolytes (CGPEs). The two different shapes of nanofiller have impacted the performance of CGPE proven by the structural analysis. It was found that both systems, the highest ionic conductivity achieved at 2.5 wt% of MnO2 and Co3O4 content with values of 6.40 and 5.2 mS cm−1, respectively. Surprisingly, the performance DSSC of Co3O4‐based CGPE was higher due to the strong Lewis's acidity of Co3O4, which absorb more iodide ions into the surface and facilitating the ions mobility. CGPE containing 2.5 wt% Co3O4 yield the highest efficiency, with value of 3.69%.

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“…Further, Arya et al. [ 111 ] comparatively studied the effect of different shapes of TiO 2 nanoparticles (nanofiller vs nanorod) on electrochemical properties of SPEs, and showed that the ionic conductivity was sensitive to the shape of nanoparticles, and the PE with the addition of TiO 2 nanorods presented superior properties (dielectric nature, electrochemical window, ionic conductivity) than that added with TiO 2 nanofillers.…”

Section: Pes For Na‐ion Batteriesmentioning

confidence: 99%

Recent Advances and Perspectives on the Polymer Electrolytes for Sodium/Potassium‐Ion Batteries

Yin

Han

Liu

et al. 2021

Small

120

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Owing to the low cost of sodium/potassium resources and similar electrochemical properties of Na+/K+ to Li+, sodium‐ion batteries (SIBs) and potassium‐ion batteries (KIBs) are regarded as promising alternatives to lithium‐ion batteries (LIBs) in large‐scale energy storage field. However, traditional organic liquid electrolytes bestow SIBs/KIBs with serious safety concerns. In contrast, quasi‐/solid‐phase electrolytes including polymer electrolytes (PEs) and inorganic solid electrolytes (ISEs) show great superiority of high safety. However, the poor processibility and relatively low ionic conductivity of Na+ and K+ ions limit the further practical applications of ISEs. PEs combine some merits of both liquid‐phase electrolytes and ISEs, and present great potentials in next‐generation energy storage systems. Considerable efforts have been devoted to improving their overall properties. Nevertheless, there is still a lack of an in‐depth and comprehensive review to get insights into mechanisms and corresponding design strategies of PEs. Herein, the advantages of different electrolytes, particularly PEs are first minutely reviewed, and the mechanism of PEs for Na+/K+ ion transfer is summarized. Then, representative researches and recent progresses of SIBs/KIBs based on PEs are presented. Finally, some suggestions and perspectives are put forward to provide some possible directions for the follow‐up researches.

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Impact of shape (nanofiller vs. nanorod) of TiO₂ nanoparticle on free‐standing solid polymeric separator for energy storage/conversion devices

Cited by 38 publications

References 92 publications

Dielectric polarization and relaxation processes of the lithium-ion conducting PEO/PVDF blend matrix-based electrolytes: effect of TiO2 nanofiller

Dielectric polarization and relaxation processes of the lithium-ion conducting PEO/PVDF blend matrix-based electrolytes: effect of TiO2 nanofiller

Comparison effect of thin microrod‐nanowhisker manganese oxide (MnO₂) and spherical grain‐like cobalt oxide (Co₃O₄) as nanofiller for performance‐enhanced composite gel terpolymer electrolyte‐based dye‐sensitized solar cells

Recent Advances and Perspectives on the Polymer Electrolytes for Sodium/Potassium‐Ion Batteries

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Impact of shape (nanofiller vs. nanorod) of TiO2 nanoparticle on free‐standing solid polymeric separator for energy storage/conversion devices

Cited by 38 publications

References 92 publications

Dielectric polarization and relaxation processes of the lithium-ion conducting PEO/PVDF blend matrix-based electrolytes: effect of TiO2 nanofiller

Dielectric polarization and relaxation processes of the lithium-ion conducting PEO/PVDF blend matrix-based electrolytes: effect of TiO2 nanofiller

Comparison effect of thin microrod‐nanowhisker manganese oxide (MnO2) and spherical grain‐like cobalt oxide (Co3O4) as nanofiller for performance‐enhanced composite gel terpolymer electrolyte‐based dye‐sensitized solar cells

Recent Advances and Perspectives on the Polymer Electrolytes for Sodium/Potassium‐Ion Batteries

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Product

Resources

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Impact of shape (nanofiller vs. nanorod) of TiO₂ nanoparticle on free‐standing solid polymeric separator for energy storage/conversion devices

Comparison effect of thin microrod‐nanowhisker manganese oxide (MnO₂) and spherical grain‐like cobalt oxide (Co₃O₄) as nanofiller for performance‐enhanced composite gel terpolymer electrolyte‐based dye‐sensitized solar cells