THE igneous oceanic crust is typically thought of as comprising two la
yers: an upper crust ('seismic layer 2') characterized by a rapid incr
ease in seismic velocity with depth, and a thicker lower crust ('seism
ic layer 3') which is distinguished from layer 2 by both a higher P-wa
ve velocity (6.69 +/- 0.26 km s(-1)) and a much smaller vertical veloc
ity gradient (<1 km s(-1) km(-1))(1-3). A direct correlation has never
been established between this seismic layering and the in situ lithol
ogical and physical properties of oceanic crust. The transition betwee
n seismic layers 2 and 3 has been variously interpreted as a change in
igneous rock texture from doleritic sheeted dykes to gabbro(4,5), an
increase in metamorphic grade from greenschist- to amphibolite-facies
rocks(2,6-9), or a change in bulk crustal porosity with depth(2,10). W
e have re-examined available seismic refraction data from around Hole
504B, the deepest (>1.8 km) continuous hole drilled into the oceanic c
rust(11-13), and find that at this location the seismic layer 2/3 boun
dary lies within the sheeted-dyke complex, where it is associated with
gradual downhole changes in crustal porosity and alteration, not a li
thological transition from sheeted dykes to gabbro.