Titanium dihydride

In the previous Sections, bulk specimens were alloyed with hydrogen from the gas phase. It was interesting to see whether hydrogen affects the mechanical properties of titanium in a similar way if metal is in a powder state and hydrogen is introduced by mechanical mixing of the metal powder with titanium dihydride, or the interparticle boundaries axe an insurmountable obstacle for hydrogen an eliminate the effects observed in bulk specimens. [Pg.433]

Compacted powder mixtures of titanium and titanium dihydride demonstrate the hydrogen-enhanced plasticity effects on deformation over 500 C, like titanium alloys hydrogenated from the gas phase. [Pg.436]

Tetraphosphorus decasulfide, 4878 Thorium dihydride, 4489 Titanium, 4919 Titanium carbide, 0561 Titanium dihydride, 4490 Zinc stearate, 3897 Zirconium, 4928... [Pg.136]

Magnesium hydride, 4463 Magnesium-nickel hydride, 4464 Plutonium(III) hydride, 4509 Poly (germanium dihydride), 4415 Poly (germanium monohydride), 4413 Potassium hydride, 4427 Rubidium hydride, 4450 Sodium hydride, 4444 f Stibine, 4510 Thorium dihydride, 4489 Thorium hydride, 4540 Titanium dihydride, 4490 Titanium-zirconium hydride, 4491 Trigermane, 4421 Uranium(III) hydride, 4511 Uranium(TV) hydride, 4541... [Pg.240]

A. Iwama, Solid Propellants Containing Titanium Dihydride , JP 28397 (1969) CA... [Pg.514]

Titanium Dihydride. The first candidate for study is TiH2 which forms a prototype dihydride system. Figure 3 indicates schematically what the calculations (14) show, which we will examine further in some detail. Titanium atoms are put together to form a metal, starting on the left with the atomic con-... [Pg.273]

Figure 3. Energy level diagram indicating modification of energy levels of titanium and hydrogen upon formation of titanium dihydride. The diagonally shaded line indicates the potential between the atoms.

Titanium azide trichloride, 4141 Titanium butoxide, 3724 Titanium carbide, 0558 Titanium diazide dibromide, 0272 Titanium dibromide, 0283 Titanium dihydride, 4484 Titanium diiodide, 4625... [Pg.2146]

Tetraphosphorus decasulfide, 4872 Thorium dihydride, 4483 Titanium, 4913 Titanium carbide, 0558 Titanium dihydride, 4484 Zinc stearate, 3891 Zirconium, 4922... [Pg.2323]

Magnesium—nickel hydride, 4458 Plutonium(III) hydride, 4504 Poly(germanium dihydride), 4409 Poly(germanium monohydride), 4407 Potassium hydride, 4421 Rubidium hydride, 4444 Sodium hydride, 4438 f Stibine, 4505 Thorium dihydride, 4483 Thorium hydride, 4535 Titanium dihydride, 4484 Titanium—zirconium hydride, 4485 Trigermane, 4415 Uranium(III) hydride, 4506 Uranium(IV) hydride, 4536 Zinc hydride, 4486 Zirconium hydride , 4487 See COMPLEX HYDRIDES, PYROPHORIC MATERIALS See entry LANTHANIDE—TRANSITION METAL ALLOY HYDRIDES... [Pg.2433]

Abstract. The interaction of hydrogen with spherical particles of an alloy such as BT5-1 containing 92.05 mass% of Ti, 4.52mass% of A1 and 3.43 mass% of Sn with diameters of particles of 0.1, 0.4, 0.6 and 0.8 mm was investigated at temperatures of 773-973 K and pressure of 1-6 MPa. It was shown that the alloy has the lower absorbed capacity on hydrogen in comparison with titanium and thermal stability of the hydrogenated alloys is lower than a stability of titanium dihydride. [Pg.321]

The thermal stability of hydrogenation products Ti(Al,Sn)H1 g is lower, than a stability of titanium dihydride. On samples thermograviagrams three endothermal effects are observed, and besides 20% of the hydrogen absorbed by an alloy is isolated already at 783 K and 823 K, and the most part of the stayed hydrogen is isolated at 900 K. [Pg.323]

Thorium oxide sulfide, 4826 Titanium dibromide, 0284 Titanium dihydride, 4490 Titanium diiodide, 4630 Titanium trichloride, 4158... [Pg.2467]

TIH2 TITANIUM DIHYDRIDE 1684 UBr3 URANIUM TRIBROMIDE 1729... [Pg.1919]

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