MOSSBAUER-SPECTROSCOPY STUDY OF THE AGING AND TEMPERING OF HIGH-NITROGEN QUENCHED FE-N ALLOYS - KINETICS OF FORMATION OF FE16N2 NITRIDE BY INTERSTITIAL ORDERING IN MARTENSITE
I. Fall et Jmr. Genin, MOSSBAUER-SPECTROSCOPY STUDY OF THE AGING AND TEMPERING OF HIGH-NITROGEN QUENCHED FE-N ALLOYS - KINETICS OF FORMATION OF FE16N2 NITRIDE BY INTERSTITIAL ORDERING IN MARTENSITE, Metallurgical and materials transactions. A, Physical metallurgy andmaterials science, 27(8), 1996, pp. 2160-2177
The distribution of nitrogen atoms in austenite and during the differe
nt stages of aging and tempering of martensite is studied by Mossbauer
spectroscopy, X-ray diffraction, and transmission electron microscopy
(TEM). Transmission Mossbauer spectroscopy (TMS) and conversion elect
ron Mossbauer spectroscopy (GEMS) are used for studying the austenite
phase where the distribution of nitrogen atoms is found to depend on t
he nitriding method, gas nitriding in our case, or ion implantation. C
onversion electron Mossbauer spectroscopy, which concerns a depth pred
ominantly less than 200 nm, reveals a nitrogen atom distribution diffe
rent from that found in the bulk by TMS. The identification and kineti
cs of the stages of aging and tempering of martensite are followed by
TMS measurements, and the phase characterization is confirmed by X-ray
diffraction and TEM. The major stages are the early ordering of nitro
gen atoms, which leads to small coherent precipitates of (alpha ''-Fe1
6N2; the passage by thickening to semicoherent precipitates of alpha '
'-Fe16N2; the dissolution of alpha '' Fe16N2 with the concomitant form
ation of gamma'-Fe4N; and the decomposition of retained austenite by t
empering. The three first stages correspond to activation energies of
95, 126, and 94 kJ/mole, respectively, consistent with the nitrogen di
ffusion for the first and third stages and the dislocation pipe diffus
ion of iron for the second.