Voltammetric and Spectroscopic Studies of α- and β-[PW12O40]3–Polyoxometalates in Neutral and Acidic Media: Structural Characterization as Their [(n-Bu4N)3][PW12O40] Salts

Ueda, Tadaharu; Kodani, Keisuke; Ota, Hiromi; Shiro, Motoo; Guo, SiXuan; Boas, John F.; Bond, Alan M.

doi:10.1021/acs.inorgchem.6b03046

Cited by 36 publications

(23 citation statements)

References 106 publications

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“…Furthermore, we postulate that due to the absence of protons in the organic electrolyte and the formation of ion pairs with the TEA cations, the most negative pH-dependent redox wave has split in two. Indeed, this behavior is similar to a previously reported splitting in organic media [40].…”

Section: Electrochemical Characterizationsupporting

confidence: 91%

Can polyoxometalates enhance the capacitance and energy density of activated carbon in organic electrolyte supercapacitors?

Zhu

Benages‐Vilau

Gómez‐Romero

2020

Electrochimica Acta

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Highlights: Tetraethylammonium phosphotungstate (TEAPW12) and activated carbon (AC) were used to prepare a hybrid electrode able to outperform AC in a high-voltage organic electrolyte supercapacitor cell.  The inorganic cluster undergoes multi-electron reactions integrated in the hybrid material, even in an aprotic organic electrolyte.  Volumetric capacitance increases by ~36% with polyoxometalates hybridization without sacrificing voltage window.  We are demonstrating for the first time the effective use of polyoxometalates in aprotic electrolyte supercapacitors.

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Section: Electrochemical Characterizationsupporting

confidence: 91%

Can polyoxometalates enhance the capacitance and energy density of activated carbon in organic electrolyte supercapacitors?

Zhu

Benages‐Vilau

Gómez‐Romero

2020

Electrochimica Acta

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“…In most cases, only the redox potential changes that depend on the concentration of acid (pH) were examined, although the redox reactions were anticipated to lead to disproportionation reactions . Recently, the detailed voltammetric behavior of the α and β forms of [PW 12 O 40 ] 3− was investigated in CH 3 CN containing n‐ Bu 4 NPF 6 in the presence of designated concentrations of acid (CF 3 SO 3 H) . The diffusion coefficients of the unprotonated POMs were calculated from cyclic voltammograms obtained in the absence of acid over the scan rate range of 20 to 500 mV s −1 and the Randles‐Sevcik equation.…”

Section: Simulationmentioning

confidence: 99%

Electrochemistry of Polyoxometalates: From Fundamental Aspects to Applications

2018

Self Cite

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Electrochemistry of polyoxometalates is very rich, as many of them can accommodate many electrons without their structure changing. Recently, extensive attention has been paid to the development of new‐generation batteries including fuel cells and redox flow batteries with polyoxometalates as catalysts. On the other hand, the detailed voltammetric behavior of polyoxometalates still remains unclear although a huge number of polyoxometalates have been prepared and characterized. This Review addresses the electrochemical properties of various polyoxometalates from fundamental and practical points of view.

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“…In 0.2 M Na 2 SO 4 aqueous acid solution (pH 2) the hybrid composite presented three successive and quasi-reversible redox processes, located at E 1/2 ((E pc +E pa )/2) +0.023, −0.251 and −0.693 V/(Ag/AgCl/KCl sat ), with the cathodic and anodic peaks separations of 72, 84, and 85 mV, respectively. In general, PWA and other Keggin hetero-polyacids structures exhibit a series of well-resolved one-electron redox processes in neutral or slightly acidic aqueous media, but they merge into two or more electron transfer reactions in strong acid aqueous solution (Sadakane and Steckhan, 1998;Ueda et al, 2017). Also, the two-electron redox activity of PWA are accompanied by protonation and pH has a strong effect on its electrochemical behavior.…”

Section: Photo-electrochromic Effectmentioning

confidence: 99%

Self-Supported Smart Bacterial Nanocellulose–Phosphotungstic Acid Nanocomposites for Photochromic Applications

Santos

Barud²,

Alencar

et al. 2021

Front. Mater.

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Bacterial nanocellulose (BNC) is a natural biopolymer obtained by gram-negative bacteria by means of a green and inexhaustible biotechnological process using glucose as producing source. BCN hydrogels is formed by cellulose nanofibrils that maintain an open network structure, an ideal matrix to produce new class of organic-inorganic nanocomposites (OIN) for multifunctional applications. The polyoxometalates (POMs) are complex molecules with several metallic ions sharing oxide ions, forming a highly symmetrical metal oxide cluster. Phosphotungstic acid (PWA), H3PW12O40 photoreduction process activated under ultraviolet irradiation, promoting color change. In this work, photochromic organic-inorganic nanocomposites were prepared by soaking phosphotungstic acid (H3PW12O40) in wet BNC membranes mats at room temperature. Semi-transparent and free-standing BNC/PWA nanocomposite with paper-like aspect were obtained. BNC network was able to control, stabilize and disperse PWA particles in a narrow nanometric distribution, and FTIR spectra indicated that the primary Keggin structure was also preserved in the nanocomposites, independently on the PWA content. The nanoparticles present a narrow distribution of around 16 nm, independently on the PWA concentration. BNC/PWA nanocomposites showed reversible photochromic behavior characteristic of the equilibrium between different tungsten oxidation states. PWA reduction (W6+→ W5+) and organic matrix oxidation is proposed to occur through a radical process involving the interaction of one electron from the oxygen atom of the PWA and one hydrogen from BNC matrix. The photochromic effect vanishes almost completely after 5 h. This mechanism is real in the presence of oxygen, however, if the membranes are left in nitrogen or under vacuum the blue color remains longer than 45 days. Photo-electrochemical behavior was studied by spectroelectrochemistry measurements. It is worth noting that all processes were still reversible in the timescale of the experiment and color changes were observed in several cycles.

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Voltammetric and Spectroscopic Studies of α- and β-[PW₁₂O₄₀]^3–Polyoxometalates in Neutral and Acidic Media: Structural Characterization as Their [(n-Bu₄N)₃][PW₁₂O₄₀] Salts

Cited by 36 publications

References 106 publications

Can polyoxometalates enhance the capacitance and energy density of activated carbon in organic electrolyte supercapacitors?

Can polyoxometalates enhance the capacitance and energy density of activated carbon in organic electrolyte supercapacitors?

Electrochemistry of Polyoxometalates: From Fundamental Aspects to Applications

Self-Supported Smart Bacterial Nanocellulose–Phosphotungstic Acid Nanocomposites for Photochromic Applications

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