Solution-Plasma-Mediated Synthesis of Si Nanoparticles for Anode Material of Lithium-Ion Batteries

Saito, Genya; Sasaki, Hirokazu; Takahashi, Hiroki; Sakaguchi, Norihito

doi:10.3390/nano8050286

Cited by 20 publications

(14 citation statements)

References 51 publications

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“…Various preparation methods are available to synthesize silica nanoparticles, such as microemulsion processing (Finnie et al 2007 ), chemical vapor deposition (Rezaei et al 2014 ), combustion synthesis (Yermekova et al 2010 ), plasma synthesis (Saito et al 2018 ), hydrothermal techniques (Gu et al 2012 ) and sol–gel processing (Prabha et al 2019 ). Major researches efforts have focused on controlling the size and morphology of nanoparticles (Brinker and Scherer 2013 ).…”

Section: Preparation Of Silica Nanoparticlesmentioning

confidence: 99%

Plant-derived silica nanoparticles and composites for biosensors, bioimaging, drug delivery and supercapacitors: a review

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Section: Preparation Of Silica Nanoparticlesmentioning

confidence: 99%

Plant-derived silica nanoparticles and composites for biosensors, bioimaging, drug delivery and supercapacitors: a review

et al. 2020

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Plasma based Synthesis and Modification of Nanomaterials

2020

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This Special Issue of Nanomaterials, including nine original research works [1][2][3][4][5][6][7][8][9], is devoted to the application of different atmospheric pressure (APP) and low-pressure (LPP) plasmas for synthesis or modification of various nanomaterials (NMs) of exceptional properties. This is followed by their structural and morphological characterization and further interesting and unique applications in different areas of science and technology. All readers interested in the capabilities of plasma-based treatments will quickly be convinced that APPs and LPPs enable one to efficiently synthesize or modify differentiated NMs using a minimal number of operations. Indeed, the procedures described in the collected articles are eco-friendly and usually involve single-step processes, thus considerably lowering labor investment and costs. As a result, the production of new NMs and their functionalization is more straightforward and can be carried out on a much larger scale, compared to other methods and procedures involving complex chemical treatments and processes. The size and morphology, as well as structural and optical properties, of resulting NMs are tunable and tailorable. In addition to leading to desirable and reproducible physical dimensions, crystallinity, functionality, and spectral properties of the resultant NMs, another benefit of plasma-based synthesis and modification is that fabricated NMs are ready-to-use prior to their specific applications, without any initial pre-treatments.Among the discharges and plasmas applied for plasma-mediated synthesis or modification of NMs, the readers can find, for example: impulse plasma in a solution initiated by spark discharge between two metallic electrodes immersed in this solution [1]; atmospheric pressure plasma jets provided by dielectric barrier discharge (DBD) operated in Ar-H 2 [2] or Ar-O 2 , Ar-N 2 , and Ar-NH 3 [5] mixtures; atmospheric pressure glow discharges (APGDs) generated in air between solid metallic electrodes and flowing solutions [3,4,6]; low-pressure capacitively coupled plasma (CCP) sustained in O 2 or N 2 between two electrodes, one being at the end of a chamber field with ionic liquids or low boiling point solvents [7]; and contact glow discharge electrolysis (CGDE) [8] or liquid phase plasma (LPP) [9], operated in both cases between two electrodes immersed in solutions of different compositions. Plasma-chemical processes and reactions occurring directly in plasmas or at interfacial zones between gaseous phases of these plasmas and liquids led to the fabrication of various metal-, nonmetal-and carbon-based NMs, including bimetallic Pd-Fe nanoparticles (NPs) formed by melting and eroding Pd-Fe electrodes [1], fructose-functionalized AgNPs [3], PVP-stabilized PtNPs [4], and pectin-stabilized AgNPs [6] (all synthesized by the reduction of appropriate ions of these metals dissolved in solutions), carbon dots (CDs) formed by irradiation of aliphatic acids dispersed in viscous media, SiNPs fabricated by melting and eroding Si electrodes u...

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“…This Special Issue of Nanomaterials, including nine original research works [ 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 , 9 ], is devoted to the application of different atmospheric pressure (APP) and low-pressure (LPP) plasmas for synthesis or modification of various nanomaterials (NMs) of exceptional properties. This is followed by their structural and morphological characterization and further interesting and unique applications in different areas of science and technology.…”

mentioning

confidence: 99%

“…Among the discharges and plasmas applied for plasma-mediated synthesis or modification of NMs, the readers can find, for example: impulse plasma in a solution initiated by spark discharge between two metallic electrodes immersed in this solution [ 1 ]; atmospheric pressure plasma jets provided by dielectric barrier discharge (DBD) operated in Ar–H 2 [ 2 ] or Ar–O 2 , Ar–N 2 , and Ar–NH 3 [ 5 ] mixtures; atmospheric pressure glow discharges (APGDs) generated in air between solid metallic electrodes and flowing solutions [ 3 , 4 , 6 ]; low-pressure capacitively coupled plasma (CCP) sustained in O 2 or N 2 between two electrodes, one being at the end of a chamber field with ionic liquids or low boiling point solvents [ 7 ]; and contact glow discharge electrolysis (CGDE) [ 8 ] or liquid phase plasma (LPP) [ 9 ], operated in both cases between two electrodes immersed in solutions of different compositions. Plasma-chemical processes and reactions occurring directly in plasmas or at interfacial zones between gaseous phases of these plasmas and liquids led to the fabrication of various metal-, nonmetal- and carbon-based NMs, including bimetallic Pd–Fe nanoparticles (NPs) formed by melting and eroding Pd–Fe electrodes [ 1 ], fructose-functionalized AgNPs [ 3 ], PVP-stabilized PtNPs [ 4 ], and pectin-stabilized AgNPs [ 6 ] (all synthesized by the reduction of appropriate ions of these metals dissolved in solutions), carbon dots (CDs) formed by irradiation of aliphatic acids dispersed in viscous media, SiNPs fabricated by melting and eroding Si electrodes under plasma heat [ 8 ], and nanocomposites supported by Fe 3 O 4 NPs on N-doped activated carbon [ 9 ]. Interestingly, NMs were also synthesized by introducing suspensions of substrates into a plasma torch (suspension-plasma spray, SPS) [ 2 ] to form Co/C, Fe/C, and Co–Fe/C NMs, containing a nanometallic phase in addition to carbide and oxide phases of Co and Fe.…”

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confidence: 99%

“…The morphological, structural, and functional properties of NMs result in their having a wide variety of applications, e.g., as catalysts for the Fischer–Tropsch synthesis of CH 4 from H 2 and CO [ 2 ], antimicrobial agents against different phytopathogenic bacteria [ 3 ], heat conductive media in heat management systems [ 4 ], necrotic agents toward cancerous cells of the human melanoma cell line [ 6 ], fluorescence sensors for detecting and measuring metal ions and flavonoids in solutions [ 7 ], and materials for the production of anodes in lithium-ion batteries [ 8 ] or electrochemical capacitor electrodes [ 9 ].…”

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