Effects of alkali-metal impurities on fracture toughness of 2090 Al-Li-Cu extrusions

Sweet, E D; Bennett, C G; Musulin, I; Lynch, S P; Nethercott, R B

doi:10.1007/BF02595445

Title: Effects of alkali-metal impurities on fracture toughness of 2090 Al-Li-Cu extrusions

Journal Article · Fri Nov 01 00:00:00 EST 1996 · Metallurgical and Materials Transactions. A, Physical Metallurgy and Materials Science

DOI:https://doi.org/10.1007/BF02595445· OSTI ID:413285

Sweet, E D; Bennett, C G; Musulin, I ^[1]; Lynch, S P; Nethercott, R B ^[2]

Comalco Research Centre, Thomastown, Victoria (Australia)
Defence Science and Technology Organisation, Melbourne, Victoria (Australia)

The effects of alkali-metal impurity (AMI) content, temperature, and crack-mouth-opening displacement (CMOD) rate on the fracture toughness of 2090-T8 Al-Li-Cu alloy extrusions were studied, particularly for short-transverse (S-L) orientations. Decreasing AMI content resulted in increasing room-temperature fracture toughness, especially for underaged S-L and T-L specimens. Unlike most Al-Li based alloys, material with very low (<2 wt. ppm) AMIs produced by vacuum refining had a high S-L fracture toughness (up to 38 MPa{radical}m for proof strengths {approximately}440 MPa) as well as high toughness in other orientations. The increase in room-temperature fracture toughness with decreasing AMI content was associated with a decrease in the proportion o brittle intergranular and cleavage-like islands, and a corresponding increase in the proportion of high energy dimpled fracture modes, on fracture surfaces. Both the present and previous studies indicate that the brittle islands result from liquid-metal embrittlement due to the presence of discrete sodium-potassium rich liquid phases. For medium to high AMI contents (5 to 37 wt ppm), S-L fracture toughness increased with decreasing temperature due to solidification of these phases and a consequent decrease in the mobility of embrittling atoms. The ability of embrittling atoms to keep up with crack tips also depended on crack velocity so that CMOD rate influenced fracture toughness. The grain structure (degree of recrystallization) appeared to be another important parameter affecting fracture toughness.

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Sponsoring Organization:: USDOE

OSTI ID:: 413285

Journal Information:: Metallurgical and Materials Transactions. A, Physical Metallurgy and Materials Science, Vol. 27, Issue 11; Other Information: PBD: Nov 1996

Country of Publication:: United States

Language:: English

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Related Subjects

36 MATERIALS SCIENCE
ALUMINIUM BASE ALLOYS
FRACTURE PROPERTIES
MICROSTRUCTURE
LITHIUM ALLOYS
COPPER ALLOYS
ALKALI METALS
METALLURGICAL EFFECTS
TEMPERATURE DEPENDENCE
CRACKS
ORIENTATION
EMBRITTLEMENT
CRACK PROPAGATION
GRAIN BOUNDARIES
SEGREGATION
LIQUIDS
PRECIPITATION

Title: Effects of alkali-metal impurities on fracture toughness of 2090 Al-Li-Cu extrusions

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