Effect of lithium on the mechanical properties of armco iron

“…In their calculations of interfacial energies using a Wigner-Seitz atomic cell model, Miedema and Broeder [31] found that an interactive term accounted for 11% of their value for nickel-lithium system and 82% of that for the nickelsodium system. However, this term was not interactive in the sense that it was concerned with the formation of a new bulk phase which might initiate cracking, as does Li2C2 for iron [11][12][13]. Concern about the possible formation of this carbide and its effect on the properties of nickel prompted us to use high-purity material in this work, but even this contained 20 p.p.m, carbon.…”

“…The atom fraction of carbon in the nickel is 1 x 10 -4 and this activity criterion could be met considering the low solubility of carbon in nickel at 250 ~ [27]. The location, habit or rate of formation of LizC2 could exert a major influence on the ductility of nickel, as it does for iron [11][12][13]. For the formation of LizC2 to be significant, the reaction must give rise to needles or sheets growing along grain boundaries, but the fractographs of samples stressed to destruction in lithium provided no supporting evidence.…”

Tensile properties of high-purity nickel stressed in alkali metal environments

“…In their calculations of interfacial energies using a Wigner-Seitz atomic cell model, Miedema and Broeder [31] found that an interactive term accounted for 11% of their value for nickel-lithium system and 82% of that for the nickelsodium system. However, this term was not interactive in the sense that it was concerned with the formation of a new bulk phase which might initiate cracking, as does Li2C2 for iron [11][12][13]. Concern about the possible formation of this carbide and its effect on the properties of nickel prompted us to use high-purity material in this work, but even this contained 20 p.p.m, carbon.…”

“…The atom fraction of carbon in the nickel is 1 x 10 -4 and this activity criterion could be met considering the low solubility of carbon in nickel at 250 ~ [27]. The location, habit or rate of formation of LizC2 could exert a major influence on the ductility of nickel, as it does for iron [11][12][13]. For the formation of LizC2 to be significant, the reaction must give rise to needles or sheets growing along grain boundaries, but the fractographs of samples stressed to destruction in lithium provided no supporting evidence.…”

Tensile properties of high-purity nickel stressed in alkali metal environments

“…lower than in vacuum. 5 The tensile strength of Fe-l7Cr-lON1 (wt %) stainless steel Is not significantly affected by lithium; 6 however, the ductility depends on strain rate and temperature.…”

Influence of a flowing lithium environment on the fatigue and tensile properties of type 316 stainless steel

“…Consequently, the modification of the microscopic and mesoscopic structure leads to embrittlement and weakening of the materials. Experimental tests of stainless steels evidence that liquid lithium corrosion reduces the ultimate tensile strength, ductility and fatigue life [14][15][16][17]. The degree of the degradation of mechanical properties depends primarily on temperature, stain rate, purity of lithium and flowing state of liquid lithium.…”

Molecular dynamics study on diffusion behavior of Li in α-Fe