Laser‐induced phonon and magnon properties of NiO nanoparticles: A Raman study

Sunny, Anoop

doi:10.1002/jrs.6067

Cited by 15 publications

(7 citation statements)

References 54 publications

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“…The Raman peaks at 355 and 515 cm À1 can be ascribed to the NiO vibrational first-order phonon (1 P) modes including transverse optical (TO) and longitudinal optical (LO) modes, while the peaks at 673, 837, and 1063 cm À1 correspond to the secondorder phonon (2 P) modes 2P TO , 2P TOþLO , and 2P LO . [38,39] XPS analyses were also performed to acquire the elemental valence and chemical composition at the surfaces of the samples. Figure 6a shows the XPS full-survey spectra of PANC, FOCNF, and NOCNF.…”

Section: Resultsmentioning

confidence: 99%

“…The Raman peaks at 355 and 515 cm −1 can be ascribed to the NiO vibrational first‐order phonon (1 P) modes including transverse optical (TO) and longitudinal optical (LO) modes, while the peaks at 673, 837, and 1063 cm −1 correspond to the second‐order phonon (2 P) modes 2P TO , 2P TO+LO , and 2P LO . [ 38,39 ]…”

Section: Resultsmentioning

confidence: 99%

“…There are also two characteristic peaks at 855.5 eV and 872.5 eV with two satellite peaks at 860.9 and 879.4 eV, corresponding to Ni 2 p 3/2 and Ni 2 p 1/2, respectively, indicating the presence of Ni 2+ in the samples. [ 39 ] The elemental compositions of PANC, FOCNF, and NOCNF are listed in Table 2 . With the increase in MOF amount in the precursors, both Fe and Ni contents increase.…”

Section: Resultsmentioning

confidence: 99%

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Embedding Metal–Organic Frameworks for the Design of Flexible Hybrid Supercapacitors by Electrospinning: Synthesis of Highly Graphitized Carbon Nanofibers Containing Metal Oxide Nanoparticles

Zhu²,

et al. 2022

Small Structures

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Electrospun carbonaceous fibers have emerged as promising electrode materials for application in energy storage devices. However, their relatively poor electrical conductivity (due to their amorphous carbon structures) and low capacitive performance lead to poor prospects for their further application. Herein, a universal synthesis of highly graphitized carbon nanofibers, containing various metal oxide nanoparticles (e.g., Fe2O3, NiO), by the pyrolysis of metal–organic framework (MOF)‐embedded electrospun nanofibers, is reported. The resulting carbon nanofibers exhibit large mesopore volumes, contain large quantities of Faradic metal oxide nanoparticles, and are highly graphitized. The fibers also have excellent mechanical flexibility, provide fast ion transfer characteristics, and a large pseudocapacitance combined with excellent electrical conductivity, leading to large specific capacitances. Consequently, asymmetric flexible hybrid supercapacitors assembled from Fe2O3‐embedded highly graphitized carbon nanofibers (FOCNF) and NiO‐embedded highly graphitized carbon nanofibers (NOCNF) exhibit a high energy density of 43.1 Wh kg−1 at a power density of 412.5 W kg−1 and possess excellent flexibility (capacitance retention of 94.4% at 180° bending and 96.2% at 30° twisting) with superior cycling stability. This strategy provides a new MOF‐based approach for the design and synthesis of multifunctional flexible carbonaceous materials and might lead to their further application in flexible energy storage devices.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Embedding Metal–Organic Frameworks for the Design of Flexible Hybrid Supercapacitors by Electrospinning: Synthesis of Highly Graphitized Carbon Nanofibers Containing Metal Oxide Nanoparticles

Zhu²,

et al. 2022

Small Structures

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“…44,45 Although the 2 M interaction is difficult to be observed in an antiferromagnetic material, 45 the 2 M band in NiO has been widely studied and its dependences with size, temperature, and defect structure, among other parameters, have been well established. [46][47][48] This band, which indicates the existence of an antiferromagnetic order in NiO, 48 arises from superexchange interactions between the next-nearest-neighboring Ni 2+ ions (NNN) in the Ni 2+ − O 2− −Ni 2+ linear atomic chain, 48,49 and in nanostructures, its existence is very sensitive to the presence of point defects. 49 For example, it has been recently reported that Cu 2+ inclusion in NiO nanoparticles results in a decrease in the intensity of the 2 M band, 50 and for bulk NiO film, it has been reported that the absence of the 2 M band responds to phenomena related to a high density of point defects that interfere with the NNN superexchange interaction.…”

Section: Resultsmentioning

confidence: 99%

“…Although the 2 M interaction is difficult to be observed in an antiferromagnetic material, 45 the 2 M band in NiO has been widely studied and its dependences with size, temperature, and defect structure, among other parameters, have been well established 46–48 . This band, which indicates the existence of an antiferromagnetic order in NiO, 48 arises from superexchange interactions between the next‐nearest‐neighboring Ni 2+ ions (NNN) in the Ni 2+ − O 2− −Ni 2+ linear atomic chain, 48,49 and in nanostructures, its existence is very sensitive to the presence of point defects 49 .…”

Section: Resultsmentioning

confidence: 99%

On the properties of NiO powders obtained by different wet chemical methods and calcination

Alastuey,

Pais Ospina,

Comedi

et al. 2023

J Am Ceram Soc.

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NiO powders were synthesized using coprecipitation, sol‐gel, and hydrothermal synthesis methods. The powders were subjected to calcination in atmospheric air, followed by recalcination in an O2‐rich atmosphere at 800°C for 2 hours each. Characterization techniques such as scanning electron microscopy, X‐ray diffraction, energy dispersive X‐ray spectroscopy, and microRaman spectroscopy were utilized. The coprecipitation and hydrothermal methods resulted in disaggregated sub‐micrometric particles. The average size of particles obtained by coprecipitation method after calcination in atmospheric air and recalcination in O2‐rich atmosphere was 360 ± 140 nm and 400 ± 130 nm, respectively. Regarding the particles obtained by hydrothermal method, the average size was 190 ± 50 and 220 ± 80 nm for calcined in atmospheric air and recalcined in O2‐rich atmosphere, respectively. Conversely, the sol‐gel method produced particle aggregates with an average size of 430 ± 150 nm after calcination in atmospheric air and 500 ± 200 nm for calcination in O2‐rich atmosphere. X‐ray diffraction analysis revealed that only the hydrothermal method yielded pure NiO without additional Ni‐related phases, irrespective of the calcination procedure. In contrast, the coprecipitation sample exhibited a Ni2O3 phase after calcination in atmospheric air, which disappeared after recalcination in an O2‐rich atmosphere. The sol‐gel‐derived sample maintained a Ni phase after both calcination processes. Analysis of the crystallite size demonstrated an increase after recalcination in an O2‐rich atmosphere for the hydrothermal and sol‐gel derived samples, while a decrease was observed for the coprecipitation‐derived sample. Raman spectra exhibited defect‐enabled first‐order forbidden phonon modes that were sensitive to the synthesis route. The two magnon phonon modes also demonstrated dependency on the route, indicating variations in defect structures. Photocatalytic evaluation using methylene blue degradation in aqueous solutions indicated better performance for the powders recalcined in an O2‐rich atmosphere.This article is protected by copyright. All rights reserved

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Yttrium‐ and nitrogen‐doped NiCo phosphide nanosheets for high‐efficiency water electrolysis

Chen,

Xiang,

Guo

et al. 2024

Carbon Energy

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Engineering high‐performance and low‐cost bifunctional catalysts for H2 (hydrogen evolution reaction [HER]) and O2 (oxygen evolution reaction [OER]) evolution under industrial electrocatalytic conditions remains challenging. Here, for the first time, we use the stronger electronegativity of a rare‐Earth yttrium ion (Y3+) to induce in situ NiCo‐layered double‐hydroxide nanosheets from NiCo foam (NCF) treated by a dielectric barrier discharge plasma NCF (PNCF), and then obtain nitrogen‐doped YNiCo phosphide (N‐YNiCoP/PNCF) after the phosphating process using radiofrequency plasma in nitrogen. The obtained N‐YNiCoP/PNCF has a large specific surface area, rich heterointerfaces, and an optimized electronic structure, inducing high electrocatalytic activity in HER (331 mV vs. 2000 mA cm−2) and OER (464 mV vs. 2000 mA cm−2) reactions in 1 M KOH electrolyte. X‐ray absorption spectroscopy and density functional theory quantum chemistry calculations reveal that the coordination number of CoNi decreased with the incorporation of Y atoms, which induce much shorter bonds of Ni and Co ions and promote long‐term stability of N‐YNiCoP in HER and OER under the simulated industrial conditions. Meanwhile, the CoN‐YP5 heterointerface formed by plasma N‐doping is the active center for overall water splitting. This work expands the applications of rare‐Earth elements in engineering bifunctional electrocatalysts and provides a new avenue for designing high‐performance transition‐metal‐based catalysts in the renewable energy field.

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Laser‐induced phonon and magnon properties of NiO nanoparticles: A Raman study

Cited by 15 publications

References 54 publications

Embedding Metal–Organic Frameworks for the Design of Flexible Hybrid Supercapacitors by Electrospinning: Synthesis of Highly Graphitized Carbon Nanofibers Containing Metal Oxide Nanoparticles

Embedding Metal–Organic Frameworks for the Design of Flexible Hybrid Supercapacitors by Electrospinning: Synthesis of Highly Graphitized Carbon Nanofibers Containing Metal Oxide Nanoparticles

On the properties of NiO powders obtained by different wet chemical methods and calcination

Yttrium‐ and nitrogen‐doped NiCo phosphide nanosheets for high‐efficiency water electrolysis

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