Decomposition of Austenite in Austenitic Stainless Steels

Abstract: Austenitic stainless steels are probably the most important class of corrosion resistant metallic materials. In order to attain their good corrosion properties they rely essentially on two factors: a high chromium content that is responsible for the protective oxide film layer and a high nickel content that is responsible for the steel to remain austenitic. Thus the base composition is normally a Fe-Cr-Ni alloy. In practice the situation is much more complex with several other elements being present, such as, … Show more

“…G phase precipitates form within the ferrite regions of duplex [21,22] and nominally austenitic stainless steels (e.g. Type 300 series austenitic steels) [13,15,16,19] during ageing within the temperature range of 250-500°C [12,14,22]. This phase typically nucleates and grows at austenite grain boundaries [21,24], and/or at austenite-a-ferrite phase boundaries but in the latter case it has a cube-on-cube orientation relationship with the ferrite [19,21].…”

“…G phase evolution in austenite is associated with exposure to higher temperatures, within a nominal range of 500-800°C [13], where the kinetics have been purported to be controlled by the rate of Si diffusion [21]. Lower ageing temperatures in austenitic stainless steels favour austenite grain boundary precipitation of G phase [12,13], whilst intragranular precipitation is observed at higher temperatures [12]. Steels with high volume fractions of G phase have been found to be embrittled [19,25] when subjected to room temperature fracture, and as such the phase promotes intergranular fracture.…”

“…Depending on the relative concentrations of Mo and Ti, the composition of the chi phase ranges from (Fe/Ni) 36 [12,24,[26][27][28], and there is potential for substitution of other elements [28]. The composition of chi phase is frequently likened to that of sigma phase, with the principle differences being the solubility of carbon [12,26] and higher concentrations of molybdenum [26,29,30].…”

“…Chi phase is a BCC intermetallic phase (a = 0.881-0.895 nm [12]) the precipitation of which only occurs in Mo-or Ti-containing stainless steels [12,26]. Depending on the relative concentrations of Mo and Ti, the composition of the chi phase ranges from (Fe/Ni) 36 [12,24,[26][27][28], and there is potential for substitution of other elements [28].…”

“…One of the less encountered precipitates is G phase, a silicon containing FCC intermetallic phase (a = 1.115-1.120 nm [12]) with a nominal composition observed in austenitic stainless steels [12][13][14][15][16][17][18][19][20] of (Ni/Fe/Cr) 16 (Nb/ Ti) 6 Si 6 [12]. By comparison, in duplex stainless steels [12,21,22] the composition is (Fe/Ni) 16 (Mn/Cr) 6 Si 7 [19]. Other studies have found that substitution of Mo for Ni is possible [14,23].…”

Precipitation within localised chromium-enriched regions in a Type 316H austenitic stainless steel

“…G phase precipitates form within the ferrite regions of duplex [21,22] and nominally austenitic stainless steels (e.g. Type 300 series austenitic steels) [13,15,16,19] during ageing within the temperature range of 250-500°C [12,14,22]. This phase typically nucleates and grows at austenite grain boundaries [21,24], and/or at austenite-a-ferrite phase boundaries but in the latter case it has a cube-on-cube orientation relationship with the ferrite [19,21].…”

“…G phase evolution in austenite is associated with exposure to higher temperatures, within a nominal range of 500-800°C [13], where the kinetics have been purported to be controlled by the rate of Si diffusion [21]. Lower ageing temperatures in austenitic stainless steels favour austenite grain boundary precipitation of G phase [12,13], whilst intragranular precipitation is observed at higher temperatures [12]. Steels with high volume fractions of G phase have been found to be embrittled [19,25] when subjected to room temperature fracture, and as such the phase promotes intergranular fracture.…”

“…Depending on the relative concentrations of Mo and Ti, the composition of the chi phase ranges from (Fe/Ni) 36 [12,24,[26][27][28], and there is potential for substitution of other elements [28]. The composition of chi phase is frequently likened to that of sigma phase, with the principle differences being the solubility of carbon [12,26] and higher concentrations of molybdenum [26,29,30].…”

“…Chi phase is a BCC intermetallic phase (a = 0.881-0.895 nm [12]) the precipitation of which only occurs in Mo-or Ti-containing stainless steels [12,26]. Depending on the relative concentrations of Mo and Ti, the composition of the chi phase ranges from (Fe/Ni) 36 [12,24,[26][27][28], and there is potential for substitution of other elements [28].…”

“…One of the less encountered precipitates is G phase, a silicon containing FCC intermetallic phase (a = 1.115-1.120 nm [12]) with a nominal composition observed in austenitic stainless steels [12][13][14][15][16][17][18][19][20] of (Ni/Fe/Cr) 16 (Nb/ Ti) 6 Si 6 [12]. By comparison, in duplex stainless steels [12,21,22] the composition is (Fe/Ni) 16 (Mn/Cr) 6 Si 7 [19]. Other studies have found that substitution of Mo for Ni is possible [14,23].…”

Precipitation within localised chromium-enriched regions in a Type 316H austenitic stainless steel

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