Ion Intercalation Process in MXene Pseudocapacitors With Aqueous and Non-Aqueous Electrolytes

AbstractThe voltage of an electrochemical cell, i.e. the difference between the chemical potentials of the two electrodes, may play the role of a sensor which allows to display the structural modifications and the physical properties. The electrochemical processes involved in an alkali metal (A) intercalation electrode emphasize the influence of the ionic and/or electronic features. The A+-lattice and A+-A+ interactions as well as electronic band-filling may lead to phase transitions or even limit the intercalation reaction.The shape of the cell voltage vs. intercalation rate curve depends on the number of vacant sites available for intercalation, the number and the oxidation state of the reducible cations, the band structure of the material and the covalency of the framework.Alkali ion intercalation in 3D-structures related to perovskite (Ln⅓ NbO3), hexagonal tungsten bronze (LiW3O9F) and Nasicon-type (AM2 (PO4)3) is discussed from that point of view.In Ln⅓NBO3 (Ln = La, Nd) (i.e. ▭ ½Ln⅓ ▭, ⅙NbO3) L1+-intercalation in various sites is related to the rare earth size.Two extra lithium atoms can be introduced into LiW3O9F in which four sites are available, but only one out of two is occupied in order to reduce the electrostatic interactions. Moreover the change in the discharge curves can be associated to the modifications with intercalation rate of the Li+-lattice interactions.Within the Nasicon derived structures of ATi2 (PO4)3 and Fe2 (MoO4)3 the intercalation process is limited by the lowest stable oxidation state of titanium or iron. In both systems the strong electronic localization leads to formation of large two phase-domains.The relevance of using 3D-intercalation electrodes in electrochemical power batteries will be discussed as far factors such as electrical behavior or absence of significant unit cell modifications of the positive electrodes during the intercalation process are essential for many cycle utilizations.

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Interface Instability during Ion Intercalation Process

ECS Meeting Abstracts ◽

10.1149/ma2017-02/4/370 ◽

2017 ◽

Keyword(s):

Interface Instability ◽

Intercalation Process ◽

Ion Intercalation

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Electrochemical Sodium Ion Intercalation Property of Na2.7Ru4O9 in Nonaqueous and Aqueous Electrolytes

ECS Meeting Abstracts ◽

10.1149/ma2012-02/15/1864 ◽

2012 ◽

Keyword(s):

Sodium Ion ◽

Aqueous Electrolytes ◽

Ion Intercalation

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An Aqueous Al-Ion Battery Boosted by Triple-Ion Intercalation Chemistry with a High-Energy MnAl 2O 4 Nanosphere Cathode

SSRN Electronic Journal ◽

10.2139/ssrn.3569552 ◽

2020 ◽

Author(s):

Wending Pan ◽

Jianjun Mao ◽

Y.F. Wang ◽

X. Zhao ◽

Y.G. Zhang ◽

...

Keyword(s):

High Energy ◽

Ion Intercalation ◽

Triple Ion

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Chemistry of Amino Acids with Aqueous Electrolytes

International Journal for Research in Applied Science and Engineering Technology ◽

10.22214/ijraset.2018.3540 ◽

2018 ◽

Vol 6 (3) ◽

pp. 2347-2348

Author(s):

Shahnawaz Mahmood

Keyword(s):

Amino Acids ◽

Aqueous Electrolytes

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1.8 V Aqueous Symmetric Carbon-Based Supercapacitors with Agarose-Bound Activated Carbons in an Acidic Electrolyte

Nanomaterials ◽

10.3390/nano11071731 ◽

2021 ◽

Vol 11 (7) ◽

pp. 1731

Author(s):

Chih-Chung Lai ◽

Feng-Hao Hsu ◽

Su-Yang Hsu ◽

Ming-Jay Deng ◽

Kueih-Tzu Lu ◽

...

Keyword(s):

Activated Carbon ◽

Sulfuric Acid ◽

Energy Density ◽

Activated Carbons ◽

High Energy ◽

Aqueous Electrolytes ◽

Alternative Material ◽

Aqueous Cells ◽

Acidic Electrolyte ◽

Cycling Behavior

The specific energy of an aqueous carbon supercapacitor is generally small, resulting mainly from a narrow potential window of aqueous electrolytes. Here, we introduced agarose, an ecologically compatible polymer, as a novel binder to fabricate an activated carbon supercapacitor, enabling a wider potential window attributed to a high overpotential of the hydrogen-evolution reaction (HER) of agarose-bound activated carbons in sulfuric acid. Assembled symmetric aqueous cells can be galvanostatically cycled up to 1.8 V, attaining an enhanced energy density of 13.5 W h/kg (9.5 µW h/cm2) at 450 W/kg (315 µW/cm2). Furthermore, a great cycling behavior was obtained, with a 94.2% retention of capacitance after 10,000 cycles at 2 A/g. This work might guide the design of an alternative material for high-energy aqueous supercapacitors.

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