Materials analysis of the TITAN-I reversed-field-pinch fusion power core
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Tailorable nano MgO.xAl<inf>2</inf>O<inf>3</inf> spinel compositions along line of homogeneity via gel combustion route: Influence on phase evolution
2019, Materials Chemistry and PhysicsCitation Excerpt :It is a stable oxide compound of spinel group exhibiting combination of good properties: high melting point (2135 °C), low thermal conductivity, good thermal shock resistance, chemical inertness, and good mechanical strength both at room temperature as well as high temperature also. Owing to these excellent combinations of features MgAl2O4 is widely applicable to refractory materials [1], catalyst supports [2], humidity sensors [3], nuclear techniques [4], insulating materials [5], military applications (domes, armor materials, etc.) [6,7], dentistry [8], and so on. Its photocatalytic degradation property [9] can be utilized as a treatment for the industrial effluents containing different toxic dye materials before releasing them into environment.
DC conductivity and AC impedance of Mn doped magnesia alumina spinel (MgAl<inf>2-2x</inf>Mn<inf>2x</inf>O<inf>4</inf>) over a large temperature range
2019, Journal of the European Ceramic SocietyCitation Excerpt :Magnesia alumina oxide (MgAl2O4) spinel (MAS, AB2O4,) has been widely researched by scientists during the past few decades, due to its many excellent properties such as high melting point (2408 K), low theoretical density (3.58 g/cm3), superior hardness, considerable mechanical strength at high temperature and good resistance against chemical corrosion [1–3]. Traditional MAS is often used as refractory material [4], transparent armor [5], insulating material [6], neutron diffraction resistance [7], catalyst-catalyst support [8] and thermal barrier coating [9] in terms of its basic properties. Further, its practical applications also play a significant role in modern society.
Recycling of LCW produced form water plants for synthesizing of nano FeO(OH), Al(OH)<inf>3</inf>, and layered double hydroxide: Effect of heat-treatment
2018, Ceramics InternationalCitation Excerpt :One of the most interested applications of LDHs is the ceramic field. Their applications in ceramics produce important category called spinels which have interested properties and many applications such as structural and refractory materials as well as electronics, fusion reactors, optical devises and medical applications [27–38]. The goal of the current work is recycling of liquid waste concentrate produced from water plants for production of interested materials as nano iron oxide hydroxide FeO(OH), aluminum hydroxide A1(OH)3, and magnesium-aluminum layered double hydroxide Mg-Al-LDH, for different applications.
Magnesium aluminate planar waveguides fabricated by C-ion implantation with different energies and fluences
2015, Nuclear Instruments and Methods in Physics Research, Section B: Beam Interactions with Materials and AtomsCitation Excerpt :This structural similarity could explain the reason of the high hardness typical of this material [7]. Because of its good resistance to radiation-induced swelling and strength degradation, magnesium aluminate is a potential fusion reactor power core insulating material [6]. However, this material has a higher IR absorption edge and required light transmission in the wavelength range of 2–5.5 μm and is now being replaced by ZnS, sapphire, AION, traditional alumina, and lanthanum niobate ceramics in applications including laser ignitors, windows for UV lithography, barcode scanners, spacecraft, watches, and night-vision systems [2,8–14].
Neutronics assessment of the shielding and breeding requirements for FNSF (standard aspect ratio)
2010, Fusion Engineering and Design
- 1
Present address: On assignment from Culham Laboratory, Abington, Oxfordshire, UK
- 2
Present address: Oak Ridge National Laboratory, Oak Ridge, TN 37831, USA.
- ∗
See p. 69 in this issue.