Reducing the Energy Band Gap of Cobalt Hydroxide Nanosheets with Silver Atoms and Enhancing Their Electrical Conductivity with Silver Nanoparticles

Suksomboon, Montakan; Kongsawatvoragul, Ketsuda; Duangdangchote, Salatan

doi:10.1021/acsomega.1c01908

Cited by 37 publications

(14 citation statements)

References 31 publications

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“…is a schematic diagram of the energy bands obtained by XPS and UV-vis tests.The calculated VB, CB and Eg of pristine Co(OH)2 are -5.69, -2.84, and 2.85 eV, which are in line with the existing research results36,37 . For discharged Co(OH)2 electrode, with the adsorption (or chemical reaction) of 𝑂𝑂𝑂𝑂 − ions with Co(OH)2 particles, the calculated VB increased to -4.81 eV.…”

supporting

confidence: 91%

Studying charge-carrier intercalation/deintercalation in energy storage materials by optical spectroscopy

Chen

Huan

Sun

et al. 2022

Preprint

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Understanding how charge-carrier intercalation/deintercalation that affects the charge-discharge process is essential for the development of efficient energy storage materials. So far, a clear understanding about the relationship of charge-discharge process of energy storage materials with the corresponding changes of energy band structure is still lacking. Here, using optical spectroscopy (RGB value, reflectivity, transmittance, UV-vis, XPS, UPS) to study α-Co(OH)2 electrode working in KOH electrolyte as research object, we provide direct experimental evidence that: 1) the intercalation of OH– ions will reduce the valence/conduction band (VB and CB) and band gap energy (Eg) values; 2) the deintercalation of OH– ions corresponds with the reversion of VB, CB and Eg to the initial values; 3) the color of Co(OH)2 electrode also exhibit regular variations in Red-Green-Blue (RGB) value during the charge-discharge process.

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supporting

confidence: 91%

Studying charge-carrier intercalation/deintercalation in energy storage materials by optical spectroscopy

Chen

Huan

Sun

et al. 2022

Preprint

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“…If the charge of the silver is positive, its interaction is electrostatic with the hydroxyl group (OH) due to its negative charge. This effect diminishes the bandgap energy as reported [51] …”

Section: Resultssupporting

confidence: 61%

“…This effect diminishes the bandgap energy as reported. [51] Thickness determination of MCM-41@Ag film Figure 8 is a topographic AFM image of a homogenous MCM-41@Ag (Sample 16) thin film deposited on top of a silicon surface. According to the profilometer analysis, the spin-coating technique's average thickness of two layers of deposited material is approximately 23 nm.…”

Section: Chemistryselectmentioning

confidence: 99%

Controlling Size Distribution of Silver Nanoparticles using Natural Reducing Agents in MCM‐41@Ag

et al. 2022

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It is by reported the effect of natural reducing agents such as plant extracts (Equisetum myriochaetum leaves, Cymbopogon citratus, Camellia sinensis, Syzygium aromaticum), fruits (orange, apple), and biopolymers (arabic gum, and chitosan) on the size distribution of silver nanoparticles, obtained by green synthesis, to be incorporated in a MCM‐41@Ag nanocomposite. The aim is to determine the influence of temperature, agitation time, concentration, atmosphere, and nature of the reducing agent on the MCM‐41@Ag particle size. According to the DLS analysis, the extract of Syzygium aromaticum produced silver nanoparticles in the range of 8–80 nm. Further structural, morphological, optical, and surface characterization confirmed the obtention of the desired MCM‐41@Ag nanocomposite. Our results show the potential of MCM‐41@Ag to be incorporated in Metal‐insulator‐semiconductor capacitors for detection purposes.

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“…From the Mott‐Schottky curves (Figure 5a), it can be seen that Ag−Co(OH) 2 (k=−0.48×10 5 ), Au−Co(OH) 2 (k=−0.69×10 5 ) and Cu−Co(OH) 2 (k=−1.0×10 5 ) catalysts have smaller tangent slope than that of Co(OH) 2 (k=−1.79×10 5 ), and the carrier concentrations are in the order of Ag−Co(OH) 2 >Au−Co(OH) 2 >Cu−Co(OH) 2 >Co(OH) 2 , indicating the improvement of the overall conductivity of the M−Co(OH) 2 catalysts, which also proves that the M−Co(OH) 2 heterostructure has faster charge transfer. In addition, Ag metals can reduce the internal resistance and improve the overall electrical conductivity, thus speeding up the charge transfer during the OER process [52] …”

Section: Resultsmentioning

confidence: 99%

“…From the Mott-Schottky curves (Figure 5a), it can be seen that AgÀ Co(OH) 2 (k = À 0. reduce the internal resistance and improve the overall electrical conductivity, thus speeding up the charge transfer during the OER process. [52] LSV curves normalized by ECSA verify the intrinsic activity of OER. As shown in Figure 5b, the AgÀ Co(OH) 2 catalyst displays the greatest current density at each potential value, which confirms the high intrinsic activity of the AgÀ Co(OH) 2 catalyst.…”

Section: Electrochemical Properties Of Catalystsmentioning

confidence: 86%

Effects of Group IB Metals of Au/Ag/Cu on Boosting Oxygen Evolution Reaction of Cobalt Hydroxide

et al. 2023

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Developing high‐activity, good‐stability oxygen evolution reaction (OER) catalysts is the key to solving the problem of hydrogen production from electrolytic water. Cobalt hydroxide (Co(OH)2) is a hopeful OER catalyst, but its poor conductivity and low inherent activity limit its OER performance. Herein, we used group IB metals of Au, Ag, and Cu to increase the OER performance of Co(OH)2 via the electrodeposition method. All three metals can increase the carrier concentration and proportion of high‐valence cobalt ions. The analysis results disclose that the construction of Ag−Co(OH)2 heterostructure can optimize the electronic structure through interfacial interactions, produce a moderate proportion of high‐valence cobalt centers, enhance the charge transport capacity and the adsorption of hydroxyl species, thus accelerating the OER kinetics and effectively improving the inherent catalytic activity. This work not only develops effective and steady catalysts but also provides a facile method to enhance the OER performance through interface engineering.

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Reducing the Energy Band Gap of Cobalt Hydroxide Nanosheets with Silver Atoms and Enhancing Their Electrical Conductivity with Silver Nanoparticles

Cited by 37 publications

References 31 publications

Studying charge-carrier intercalation/deintercalation in energy storage materials by optical spectroscopy

Studying charge-carrier intercalation/deintercalation in energy storage materials by optical spectroscopy

Controlling Size Distribution of Silver Nanoparticles using Natural Reducing Agents in MCM‐41@Ag

Effects of Group IB Metals of Au/Ag/Cu on Boosting Oxygen Evolution Reaction of Cobalt Hydroxide

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