A study of the Ulleung Basin in the southwestern East Sea (Sea of Japan), b
ased on single- and multi-channel seismic reflection profiles and ocean bot
tom seismometer (OBS) data, suggests that the basin formed largely by pull-
apart opening and the deep, northern basin is underlain by thicker-than-nor
mal oceanic crust (10 km thick), probably formed during the earliest stage
of seafloor spreading. Volcanic activity in association with basin opening
occurred over much of the basin but it ceased first in the south while it c
ontinued in the north until recently. The principal evidence for pull-apart
opening includes: (1) an overall rhomboidal shape of the basin consisting
of two basement lows and a median high, known to be characteristic of pull-
apart basins; (2) the location and orientation of the major volcanic source
s suggesting more-or-less N-S opening; and (3) the strike-slip fault system
along the western basin margin, which appears to have guided the pull-apar
t opening. The lack of extensional deformation along the western basin marg
in, which would have been prevalent if SW Japan had rotated away from the K
orean Peninsula as suggested by paleomagnetic data, is also not in favor of
the alternative, rotational opening of the basin. The absence of graben-an
d-rift topography in the acoustic basement in the deep, northern Ulleung Ba
sin is indicative of the non-brittle or ductile nature of the crust. Tau-p
analysis of the OBS data reveals that the igneous crust consists of upper a
nd lower layers with velocities typical of oceanic layers. The velocity-dep
th profiles with a two-gradient velocity structure is also characteristic o
f oceanic crust. However, the lower layer is much thicker than oceanic laye
r 3 and the change of velocity gradient, which occurs at around 6.5 km/s in
typical oceanic crust, occurs at about 6 km/s, suggesting that the crust i
s not a typical oceanic crust. The meager basin size and short opening peri
od may suggest that the basin opening did not lead to the formation of full
-fledged oceanic crust but instead resulted in embryonic or incipient ocean
ic crust thickened by upper-mantle thermal perturbations evoked by rifting.
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