M. B. Rahaei scite author profile

NiAl-xTiC nanostructured composite powders [x50, 1, 3, 6 and 10 volume fraction per cent (vf % )] were produced by high energy ball milling of Ni, Al and nano-TiC powders. Sintering of prepared nanostructured NiAl powder using hot pressing resulted in an ultrafine grained NiAl intermetallic with a high relative density, while addition of TiC nanoparticles seriously inhibited grain growth and slightly decreased the relative density of nanostructured NiAl. It was found that the addition of nano-TiC reinforcement up to 10 vf % resulted in stabilisation of nanostructured NiAl in nanocomposite products.

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High‐yield synthesis of multi‐walled carbon nanotube by hydrothermal method

Manafi

Rahaei

Elli

et al. 2010

Can J Chem Eng

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The evolution of multi-walled carbon nanotubes (MWCNTs) under hydrothermal condition was investigated, because the hydrothermal method (HTM) has been utilised for commercial production of advanced engineering materials. To synthesise MWCNTs by hydrothermal process using mixed aqueous solution diethylenetriamine, polyethyleneglycol (PEG) and NaOH were used as starting materials. We investigated the effect of hydrothermal temperature, time, and amount of formative compounds. Hydrothermal reaction temperature was in the range from 150 to 180 • C. The aim of the present work is to presentation hydrothermal synthesis as a new processing method for fabrication of MWCNTs, without the addition of metal catalyst. The homogeneity of hydrothermal processes, cheapness, and availability of amorphous carbon materials, without the need of catalyst, are advantages favouring the scaling-up of the new method. The treatment of higher volumes would only require autoclaves with increasing load-bearing capacity. Synthesised MWCNTs were analysed with a scanning electron microscope (SEM), a high resolution transmission electron microscope (HRTEM), thermo-gravimetric analysis (TGA), and Raman spectroscopy. This result also presented a controllable way to synthesise MWCNTs with high purity. Indeed, present work will introduce new chapter in synthesising MWCNTs for scientific and engineering.On aétudié l'évolution de nanotubes de carboneà parois multiples (NTCPM) sous condition hydrothermiqueà cause du fait que la méthode hydrothermique (HTM) aété utilisée pour la production commerciale de matériaux d'ingénierie perfectionnés. Afin de synthétiser des NTCPM par processus hydrothermique en utilisant une solution aqueuse mixte, de la diéthylènetriamine, du polyéthylène-glycol (PEG) et NaOH ontété utilisés comme matériaux de départ. Nous avonsétudié l'effet de la température hydrothermique, de la durée et de la quantité de composants formateurs. La température de réaction hydrothermique se situait dans l'intervalle de 150 • Cà 180 • C. L'objectif du travail présent est de présenter la synthèse hydrothermique comme une nouvelle méthode de traitement pour la fabrication de nanotubes de carboneà parois multiples, sans l'ajout d'un catalyseur métallique. L'homogénéité des processus hydrothermiques, le faible coût et la disponibilité de matériaux de carbone amorphe, sans le besoin de catalyseur, sont des avantages en faveur de la miseà l'échelle de la nouvelle méthode. Le traitement de volumes supérieurs ne nécessiterait que des autoclaves avec des capacités supérieures de charge et force portante. Des NTCPM synthétisés ontété analysés avec un microscopeélectroniqueà balayage (MEB), un microscopeélectroniqueà transmission de haute résolution (METHR), une analyse thermogravimétrique (TGA) et une spectroscopie Raman. Ce résultat offraitégalement un moyen contrôlable de synthétiser des NTCPM de haute purité. En fait, ce travail va ouvrir un nouveau chapitre de la synthèse des NTCPMà des fins scientifiques et d'ingénierie.

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In-Situ Manufacturing of NiAl-TiC Composites with Three Dimensional (3D) Discrete Particular Network and Bi-Continuous Microstructures

Rahaei

2019

Advanced Powder Technology

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M. B. Rahaei

Mechanochemical synthesis of nano TiC powder by mechanical milling of titanium and graphite powders

Stabilization of nanostructured materials using fine inert ceramic particles

Sintering behaviour of NiAl–xTiC nanostructured composite powders (x = 0, 1, 3, 6 and 10 vf_%) during hot pressing

High‐yield synthesis of multi‐walled carbon nanotube by hydrothermal method

In-Situ Manufacturing of NiAl-TiC Composites with Three Dimensional (3D) Discrete Particular Network and Bi-Continuous Microstructures

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M. B. Rahaei

Mechanochemical synthesis of nano TiC powder by mechanical milling of titanium and graphite powders

Stabilization of nanostructured materials using fine inert ceramic particles

Sintering behaviour of NiAl–xTiC nanostructured composite powders (x = 0, 1, 3, 6 and 10 vf%) during hot pressing

High‐yield synthesis of multi‐walled carbon nanotube by hydrothermal method

In-Situ Manufacturing of NiAl-TiC Composites with Three Dimensional (3D) Discrete Particular Network and Bi-Continuous Microstructures

Contact Info

Product

Resources

About

Sintering behaviour of NiAl–xTiC nanostructured composite powders (x = 0, 1, 3, 6 and 10 vf_%) during hot pressing