120 Prakt. Met. Sonderband 30 (1999) 
a-Ni solid solution phase (3). The decrease of dendrite solidification velocity at highest achieved 
undercooling levels could be ascribed to the temperature dependent diffusion coefficient in the melt 
(9) in the same way as in the theory of eutectic solidification (10, 11). 
3.2 Microstructure and phase analysis of as-solidified samples 
Structure and composition of the respective phases cannot be inferred from in situ measurements of 
recalescence behavior but must be determined in the as-solidified samples itself. From the equilib- 
rium phase diagram (5) (compare Fig. 1) we expect a two-phase microstructure of a-Ni and ßı- 
Ni3Si (or ß3-Ni3Si) for the eutectic melt composition Ni-21.4 at.% Si. Indeed, no trace of additional 
metastable phase was observed in as-cast ingots. Gas cooled moderately undercooled samples (AT = 
70 K) exhibit the lamellar two-phase microstructure with lamellar spacings of A ~ 1.0 pm along 
with areas of an anomalous eutectic microstructure. 
af +I 
EN] mss 
AN AT 
ARLE 
_ sn] 
Fig. 3a-d: Cross-sectional SEM-micrographs of gas-cooled and substrate-quenched eutectic Ni- 
21.4 at.% Si undercooled drops. (a) fine-grained anomalous eutectic microstructure near the sample 
surface and (b) coarse anomalous eutectic microstructure in the centre of a gas-cooled sample with 
AT = 200 K; (c) substrate-quenched sample with AT = 235 K showing a narrow layer of the me- 
tastable phase (greyish appearance) in the vicinity of the substrate contact (bottom) and (d) the de- 
composed two-phase microstructure in 1 mm distance from the melt-substrate interface