PHYSICOCHEMICAL INTERACTION OF MANGANESE WITH NIOBIUM (in Russian)
Microstructural, x-ray phase, and thermal analyses as well as hardness and microhardness determinations were performed on different manganese alloys containing 2.26, with a small Nb content have a two-phase structure characteristic of a eutectic. With increasing Nb content, an increasing amount of an intermetallic compound is formed. With a 2.98 wt.% Nb alloy interference lines of only alpha -Mn with a lattice parameter a = 8.892 kX in the annealed state or of ore resistant t -Mn with a lattice parameter a = 6.290 kX in the molten state can be detected by x-ray analysis. With 5.64 wt.% Nb, lines of a new phase can be detected whose intensities increase with increasing Nb content. This new phase is an intermetallic compound Mn/sub 2/Nb Laves phase with a structure of the MgZn/sub 2/ type. The lattice parameters of the Mn/sub 2/Nb phase are: a = 4.881 kX, c = 7.953 kX, c/a = 1.629. With increasing niobium content the hardness values fall from 900 to 950 hg/mm/sup 2/ for pure manganese to 650 to 700 kg/mm/sup 2/ for the 29.85 wt.% niobium alloy. The hardness of the intermetallic compound is less than the hardness of the alpha -Mn. Thermal analysis showed that additions of niobium to manganese significantly increased the temperature of the alpha = ore resistant t transition which is shifted from 727 tained C for pure manganese to 800 tained C for the alloys. A ore resistant t transition takes place at 1135 tained C by a peritectic reaction. Fusion of a eutectic mixture of -Mn and Mn/sub 2/ Nb occurs at 1220 tained C. The intermetallic compound MnNb melts at 1500 tained C. A phase diagram for the Mn-Nb system is constructed on the basis of these resuits. (TTT) Iodide-derived titanium (99.97%) and neodymium (99.8%) were fused in an electric arc furnace in a helium atmosphere to prepare nine alloys with a necdymium content of 0 to 10%. Smelted and forged samples were annealed in evacuated quartz ampoules for 25 hours at 1000 tained C and 100 hours at 850 tained C. Samples of alloys were quenched in water from temperatures of 600, 800, 850, 890, 920, 1000, and 1100 tained C to determine the state of the system at higher temperatures. Microscopic analyses of phases showed that addition of neodymium stabilizes the alpha -phase. The microhardness of the phase is about 70 kg/mm/sup 2/. Apparently, no intermetallic compounds are formed in the Ti-Nd system. The limiting saturation of the alpha -solid solution at 600 tained C is 1.8 wt.% Nd, as determined from microhardness values on quenched samples of variable neodymium composition. The solubility of neodymium is somewhat greater than the solubility of lanthanum and cerium in alpha -titunium because of the lanthanide contraction. Brinnell hardness values, yield strength, elongation, and reduction in cross- section area were also determined at room temperature. Neodymium is more effective than lanthanum or cerium in increasing the handness and strength of titanium. Small additions of Nd(0.5%) decrease the plasticity slightly. The addition of 1.2 wt.% Ce increases the yield strength of titanium from 32 to 38 to 40 hg/mm/sup 2/, while the same amount of neodymium increases the yield strength to 48 to 50 kg/mm/sup 2/. The strength of Ti-Nd alloys continues to increase even with the appearance of a second phase in the alloy, while in the TiLa and Ti- Ce systems a decrease in strength and a sharp drop in plasticity occurs upon the appearance of a second phase. The solubility of neodymium in alpha -titanium varies considerably with temperature. Hence, a noticeable aging effect can be expected, but this must be confirmed by experiment. (TTT)
- Research Organization:
- Baikov Inst. of Metallurgy, Academy of Sciences, USSR
- NSA Number:
- NSA-14-019473
- OSTI ID:
- 4137677
- Journal Information:
- Zhur. Neorg. Khim., Journal Name: Zhur. Neorg. Khim. Vol. Vol: 5
- Country of Publication:
- Country unknown/Code not available
- Language:
- Russian
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Related Subjects
ANNEALING
CHEMICAL REACTIONS
CONFIGURATION
EUTECTICS
EXPANSION
HARDNESS
HIGH TEMPERATURE
IMPURITIES
INTERFERENCE
INTERMETALLIC COMPOUNDS
LATTICES
LAVES PHASES
MAGNESIUM ALLOYS
MANGANESE
MANGANESE-ALPHA
MANGANESE-BETA
MANGANESE-GAMMA
MELTING
METALLOGRAPHY
METALS, CERAMICS, AND OTHER MATERIALS
NIOBIUM
PHASE DIAGRAMS
QUANTITATIVE ANALYSIS
QUANTITY RATIO
REACTION KINETICS
SPECTRA
STANDARDS
TEMPERATURE
THERMAL ANALYSIS
X RADIATION
ZINC ALLOYS