Study of morphology, magnetic properties, and visible magnetic circular dichroism of Ni nanoparticles synthesized in SiO<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:msub><mml:mrow /><mml:mn>2</mml:mn></mml:msub></mml:math>by ion implantation

Édelman, I. S.; Petrov, D. A.; Ivantsov, R. D.; Жарков, С. М.; Великанов, Д. А.; Гумаров, Г. Г.; Нуждин, В. И.; Валеев, В. Ф.; Степанов, А. Л.

doi:10.1103/physrevb.87.115435

Cited by 18 publications

(8 citation statements)

References 71 publications

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“…The polyelectrolytesmodified PS beads bearing a negative surface charge were able to attract positively charged, 4-dimethylaminopyridine-coated Au nanoparticles in chemical solutions. Similar electrostatic approach has been used to prepare SiO 2 -Ni composite particles [26,27]. These findings shed lights on using the electrostatic LbL assembly to form metallic nuclei on surface of SiO 2 core preferentially so that the nucleated sites may grow into a continuous metal deposition via the electroless plating.…”

Section: Introductionmentioning

confidence: 73%

“…Routes to synthesize the composite particles with tailored hierarchical structures include, for example, preferential surface precipitation, seeded growth, Pickering emulsion, electroless (autocatalytic) plating, sonochemistry, and electrostatic layer-by-layer (LbL) assembly [9,10,[13][14][15][16][17][18][19]. Among them, the electroless plating involves use of chemical reducing agent to facilitate reduction of metallic ions in solution so that metallic nuclei can deposit preferentially on the core surface of various chemical compositions, forming either a uniform metal shell or a raspberry core-shell structure so long as a continuous electron transfer between the reacting species can occur selectively at specific activation sites on the core surface [3,9,10,[20][21][22][23][24][25][26][27][28][29][30][31]. The process is facile with a good throwing power, and is also flexible and cost-effective.…”

Section: Introductionmentioning

confidence: 99%

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Electroless nickel metallization to prepare SiO2–Ni composite particles via polyelectrolytes route

Tseng

2015

Ceramics International

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Section: Introductionmentioning

confidence: 73%

Section: Introductionmentioning

confidence: 99%

Electroless nickel metallization to prepare SiO2–Ni composite particles via polyelectrolytes route

Tseng

2015

Ceramics International

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“…[ 103 ] Recently, a number of literature have been published on the formation of hollow NPs and synthesis of core–shell NPs by one‐ or two‐step ion implantation. [ 104,106–118 ] In addition, specific nuclei‐shell structures such as multilayer NPs can also be synthesized by ion implantation in the simple operating steps. Ren et al performed the fabrication of sandwiched structure of NPs (i.e., Ag shell–nanovoid‐Ag core NPs) by one‐step ion implantation with Ag fluence as high as 2 × 10 17 ions cm −2 , as depicted in Figure .…”

Section: Ion Beam Synthesis Of Nanoparticlesmentioning

confidence: 99%

Plasmonic Nanoparticles in Dielectrics Synthesized by Ion Beams: Optical Properties and Photonic Applications

Pang

et al. 2020

Advanced Optical Materials

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The zero‐dimensional metallic nanoparticles (NPs) have attracted tremendous attention in various areas owing to the collective oscillation of electron gas that couples with electromagnetic field, known as localized surface plasmon resonance (LSPR). In practical applications, the tailoring of LSPR effect is of significant importance for promising photonic devices with designed nanocomposite systems and enhanced optical properties. Ion beam technology has been demonstrated to be an efficient method to fabricate NPs embedded in dielectrics for LSPR tailoring and material modification. By manipulating the parameters of ion beams, the shape, size, and structure of NPs can be well controlled, which enables the dielectrics to possess novel linear and nonlinear optical properties. In this review, the latest research progress on the ion beam synthesis of various NPs is systematically summarized. The tailoring of linear and nonlinear optical properties of dielectrics by NPs is discussed in detail. Selected applications are presented to indicate the development of the plasmonic NPs in dielectric systems for photonic applications.

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“…Superparamagnetism has been known for decades [1]; however, the interest in this fundamental phenomenon has increased in recent years in connection with a wider use of spintronic devices consisting of nanoscale magnetic components [2]. Although the best way to study superparamagnetism is by exploring the superparamagnetic behavior of an individual nanoparticle, so far due to technical challenges the study of superparamagnetism has been mainly performed with ensembles of magnetic nanoparticles where the fluctuations are not observed directly but inferred from the field and temperature dependence of the average magnetization of the ensemble [3][4][5][6][7][8].The magnetic fluctuations of an individual superparamagnetic nanoparticle are described in the framework of the Néel-Brown model [9][10][11]. In its simplest form, the model describes a thermally activated process of coherent rotation of a single magnetic domain particle with uniaxial magnetic anisotropy at a temperature T over an energy barrier E b , and it predicts an average waiting time for reversal τ given by τ = τ 0 e E b /kB T , where τ 0 is a sample specific constant linked to Larmor frequency with a typical value on the order of 10 −9 s [12].…”

mentioning

confidence: 99%

Monitoring superparamagnetic Langevin behavior of individual SrRuO3nanostructures

2014

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Patterned nanostructures on the order of 200 nm × 200 nm of the itinerant ferromagnet SrRuO3 give rise to superparamagnetic behavior below the Curie temperature (∼ 150 K) down to a sampledependent blocking temperature. We monitor the superparamagnetic fluctuations of an individual volume and demonstrate that the field dependence of the time-averaged magnetization is well described by the Langevin equation. On the other hand, the rate of the fluctuations suggests that the volume in which the magnetization fluctuates is smaller by more than an order of magnitude. We suggest that switching via nucleation followed by propagation gives rise to Langevin behavior of the total volume, whereas the switching rate is determined by a much smaller nucleation volume.PACS numbers: 75.60.Jk, The magnetization of ferromagnetic nanoparticles commonly exhibit thermally induced fluctuations known as a superparamagnetic behavior at a temperature interval below the Curie temperature. Superparamagnetism has been known for decades [1]; however, the interest in this fundamental phenomenon has increased in recent years in connection with a wider use of spintronic devices consisting of nanoscale magnetic components [2]. Although the best way to study superparamagnetism is by exploring the superparamagnetic behavior of an individual nanoparticle, so far due to technical challenges the study of superparamagnetism has been mainly performed with ensembles of magnetic nanoparticles where the fluctuations are not observed directly but inferred from the field and temperature dependence of the average magnetization of the ensemble [3][4][5][6][7][8].The magnetic fluctuations of an individual superparamagnetic nanoparticle are described in the framework of the Néel-Brown model [9][10][11]. In its simplest form, the model describes a thermally activated process of coherent rotation of a single magnetic domain particle with uniaxial magnetic anisotropy at a temperature T over an energy barrier E b , and it predicts an average waiting time for reversal τ given by τ = τ 0 e E b /kB T , where τ 0 is a sample specific constant linked to Larmor frequency with a typical value on the order of 10 −9 s [12]. The temperature below which the waiting time exceeds the relevant measuring time (commonly on the order of 100 s) is defined as the blocking temperature T b given by T b = 25K u V /k B , where K u , V , and k B are the anisotropy constant, the volume of the sample, and Boltzmann constant, respectively.The field dependence of the average magnetization − → M is described by the Langevin equation, where µ 0 − → H is the magnetic field. The application of the Langevin equation to describe the magnetization curves of ensembles of nanoparticles is not straightforward due to variations in the volume and shape of the nanoparticles. Therefore, any fit requires making assumptions regarding the volume distribution [13]. On the other hand, in the few reports where superparamagnetic fluctuations of individual superparamagnetic nanoparticles were monitored [14][15][1...

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Study of morphology, magnetic properties, and visible magnetic circular dichroism of Ni nanoparticles synthesized in SiO2by ion implantation

Cited by 18 publications

References 71 publications

Electroless nickel metallization to prepare SiO2–Ni composite particles via polyelectrolytes route

Electroless nickel metallization to prepare SiO2–Ni composite particles via polyelectrolytes route

Plasmonic Nanoparticles in Dielectrics Synthesized by Ion Beams: Optical Properties and Photonic Applications

Monitoring superparamagnetic Langevin behavior of individual SrRuO3nanostructures

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