Nano‐SiO<sub>2</sub> Doped Polystyrene Materials for Inertial Confinement Fusion Targets

Sang, Xiao; Yang, Xiaodong; Cui, Zhenduo; Zhu, Shengli; Sheng, Jing

doi:10.1081/mb-200049806

Cited by 12 publications

(5 citation statements)

References 16 publications

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“…3b), which implied that the treated nano-SiO 2 was coated successfully by KH-550. [10] C was present in all of the samples, including untreated nano-SiO 2 , presumably as a contaminant. Figure 4 shows SEM micrographs of nano-SiO 2 /epoxy composites with different nanoSiO 2 contents.…”

Section: Thermogravimetric Analysis (Tga)mentioning

confidence: 96%

Preparation and Properties of Nano‐SiO₂/Epoxy Composites Cured by Mannich Amine

Zhu

Yang

Cui

et al. 2006

Journal of Macromolecular Science, Part B

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Nano-SiO 2 /epoxy composites cured by Mannich Amine (type T-31) were prepared and studied and the results are reported in this paper. The nano-SiO 2 was pretreated by a silane coupling agent (type KH-550) and mixed with epoxy resin (type E-51) using an ultrasonic processor. Amounts of filler loading ranged from 1% to 5% of the weight of the epoxy resin. Some properties of the resulting composites were characterized by X-ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM), and thermogravimetric analysis (TGA). The results of tensile tests and impact tests showed that the composite with 3% nano-SiO 2 loading presented the best mechanical performances. The tribological performance and thermal stability of the materials were also improved with the addition of nano-SiO 2 .

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Section: Thermogravimetric Analysis (Tga)mentioning

confidence: 96%

Preparation and Properties of Nano‐SiO₂/Epoxy Composites Cured by Mannich Amine

Zhu

Yang

Cui

et al. 2006

Journal of Macromolecular Science, Part B

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“…These advanced targets all have characteristics to produce high accelerated ions in carbon-hydrogenated plasmas and, as thick, to generate extractable high ion current using repetition rate lasers. The prepared advanced target can be used as high yield of proton and carbon ion source for many applications, such as LIS to inject pre-accelerated ions in superconducting cyclotrons of INFN-LNS in Catania (Italy) (Gammino et al, 2004), production of 10-100 MeV proton and carbon ions for hadrontherapy according to aims of the ELIMED Project (Schillaci et al, 2014), production of hot hydrogenated plasmas for astrophysical studies in the field of nuclear reactions induced in light nuclei and plasma Coulomb screening effects (Torrisi, 2014b), and inertial confinement fusion using composite pellets based on deuterium and tritium polymers containing high carbon nanoparticles (CNP) concentrations (Sang et al, 2005).…”

Section: Resultsmentioning

confidence: 99%

Laser-generated plasmas by graphene nanoplatelets embedded into polyethylene

et al. 2017

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Graphene micrometric particles have been embedded into polyethylene at different concentrations by using chemical–physical processes. The synthesized material was characterized in terms of mechanical and optical properties, and Raman spectroscopy. Obtained targets were irradiated by using a Nd:YAG laser at intensities of the order of 1010 W/cm2 to generate non-equilibrium plasma expanding in vacuum. The laser–matter interaction produces charge separation effects with consequent acceleration of protons and carbon ions. Plasma was characterized using time-of-flight measurements of the accelerated ions. Applications of the produced targets in order to generate carbon and proton ion beams from laser-generated plasma are presented and discussed.

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“…proteger encimas de los esfuerzos cortantes en reactores tradicionales, proteólisis de microorganismos y reacciones hidrofóbicas) (Caussette, et al, 1999), (Colombié, Gaunand, & Lindet, 2001), (Bommarius & Karau, 2005), provee estabilidad para fármacos (e.g. protección contra fluidos biológicos) (Barrat, 2002), (Allen & Cullis, 2004), aumenta la bio-compatibilidad de fármacos convencionales y permite la dosificación controlada de moléculas activas (Wise, et al, 2000), (Yang, Qiao, Hong, & Dong, 2013), (Siepman & A, 2001), elimina incompatibilidades, sirve de material inerte para el confinamiento de elementos incompatibles (Sang, Yang, Cui, Zhu, & Sheng, 2005), es usada para fabricar micro reactores (Ikeuchi, Tane, & Ikuta, 2012), (Murphy & Wudl, 2010), andamios para cultivar tejidos, (Sukhorukov, Fery, & Mohwald, 2005), y se usa para construir rellenos livianos/flotación, separadores o amortiguadores (Shchukin & Sukhorukov, 2004). Las microcápsulas también pueden ser empleadas como células artificiales, (Ouyang, et al, 2004) como cubiertas protectoras para encimas y tejidos (Cao, 2005) (Colvin, 2003), o como vectores de transferencia para terapia genética (Selvam, et al, 2006;Baker, 2010), dispersantes de colorantes (Luo Yan, 2002), sistemas de purificación de agua (Sohn, et al, 2012), electrodos (Lee, Jung, & Oh, 2003), almacenadores de gas (Tamae, Sumi, & Yasuda, 1996), catalizadores, (Ikeda, et al, 2006) cosméticos (Cheng, et al, 2009).…”

Section: Introductionunclassified

Microcápsulas Vacías Empleadas en Aplicaciones de Ultrasonidos: Generalidades, Usos y Métodos de Fabricación

Molino

2019

ESJ

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Resumen Debido a su baja densidad, dispersión óptica, buen aislamiento térmico y grandes contenedores, las microcápsulas vacías han adquirido una especial relevancia en el campo farmacéutico y tecnológico como en la industria de cosméticos, recubrimientos, tintas, catálisis, estándares de columna de cromatografía, rellenos, biorreactores, fotocopiado electrónico, terapia génica, administración focalizada de fármacos o incluso en diagnóstico por imágenes de ultrasonido. Una microcápsula vacía se define como micro burbujas (CO2, N2, perfluorocarbonos "PFC") encapsuladas en una capa delgada de polímero o proteína. Si se emplean en aplicaciones de imágenes de ultrasonido, una capa lo suficientemente delgada permite que el núcleo de gas de la microcápsula oscile en presencia de un campo acústico para que la frecuencia de diagnóstico se pueda reflejar adecuadamente. Además, estas cápsulas deben ser no tóxicas, biocompatibles y biodegradables en el cuerpo humano. Esta revisión se centra en la síntesis de microcápsulas poliméricas biodegradables vacías que pueden emplearse como agentes de contraste de ultrasonido o en cualquier otra aplicación biomédica, donde los tamaños pequeños, la uniformidad y la toxicidad son parámetros cuando se fabrican dichas cápsulas.

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Nano‐SiO₂ Doped Polystyrene Materials for Inertial Confinement Fusion Targets

Cited by 12 publications

References 16 publications

Preparation and Properties of Nano‐SiO₂/Epoxy Composites Cured by Mannich Amine

Preparation and Properties of Nano‐SiO₂/Epoxy Composites Cured by Mannich Amine

Laser-generated plasmas by graphene nanoplatelets embedded into polyethylene

Microcápsulas Vacías Empleadas en Aplicaciones de Ultrasonidos: Generalidades, Usos y Métodos de Fabricación

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Nano‐SiO2 Doped Polystyrene Materials for Inertial Confinement Fusion Targets

Cited by 12 publications

References 16 publications

Preparation and Properties of Nano‐SiO2/Epoxy Composites Cured by Mannich Amine

Preparation and Properties of Nano‐SiO2/Epoxy Composites Cured by Mannich Amine

Laser-generated plasmas by graphene nanoplatelets embedded into polyethylene

Microcápsulas Vacías Empleadas en Aplicaciones de Ultrasonidos: Generalidades, Usos y Métodos de Fabricación

Contact Info

Product

Resources

About

Nano‐SiO₂ Doped Polystyrene Materials for Inertial Confinement Fusion Targets

Preparation and Properties of Nano‐SiO₂/Epoxy Composites Cured by Mannich Amine

Preparation and Properties of Nano‐SiO₂/Epoxy Composites Cured by Mannich Amine