Acicular ferrite: Difference between revisions
m Date maintenance tags and general fixes using AWB |
rmv orphan temp |
||
| Line 1: | Line 1: | ||
{{Orphan|date=April 2007}} |
|||
{{Expert-subject|chemistry|date=November 2008}} |
{{Expert-subject|chemistry|date=November 2008}} |
||
{{Context|date=October 2009}} |
{{Context|date=October 2009}} |
||
Revision as of 19:52, 14 October 2009
 | This article needs attention from an expert in chemistry. Please add a reason or a talk parameter to this template to explain the issue with the article. (November 2008) |
 | This article provides insufficient context for those unfamiliar with the subject. (October 2009) |
Acicular ferrite consists of a fine structure of interlocking ferrite plates (sometimes called 'dark etching').
Acicular ferrite is formed in the interior of the original austenitic grains by direct nucleation from the inclusions, resulting in randomly oriented short ferrite needles with a 'basket weave' appearance. This interlocking nature, together with its fine grain size (0.5 to 5 um with aspect ratio from 3:1 to 10:1), provides maximum resistance to crack propagation by cleavage. Acicular ferrite is also characterised by high angle boundaries between the ferrite grains. This further reduces the chance of cleavage, because these boundaries impede crack propagation. It is reported that nucleation of various ferrite morphologies is aided by nonmetallic inclusion; in particular oxygen-rich inclusions of a certain type and size are associated with the intragranular formation of acicular ferrite. Acicular ferrite is a fine Widmanstätten constituent, which is nucleated by an optimum intragranular dispersion of oxide/sulfide/silicate particles.
Composition control of the weld metal is necessary in order to maximise the volume fraction of acicular ferrite, because excessive alloying elements can cause the formation of bainite and martensite.
See also
References
 |
External links
 | This material-related article is a stub. You can help Wikipedia by expanding it. |