Basalts are volumetrically the most significant rock type sampled, and to date have provided the bulk of the compositional information we have about the processes of melt generation, transport and crystallization that create the oceanic crust. Progress in the study of basalts over the past 4 years has included new insights into and refinement of our knowledge of the global variability of the chemical compositions of MORB [ Langmuir et al., 1992]), further characterization of the extent of compositional variability exhibited by basalts sampled from individual segments of the global ridge system, links between compositional variability and observed temporal and spatial relationships, determination of chemical signatures of basalts that convey information about the nature of the mantle source, as well as characteristics of the melt transport processes, and the development of new methods for determining the relative ages of these very young basalts.
Sinton et al. [1991] interpreted the scales and kinds of magmatic
variations
observed at the superfast spreading southern East Pacific Rise (EPR) to
indicate that the
regional temperatures of the upwelling asthenosphere, magma supply to the
axis, and crustal
magmatic temperatures reflect independent, regionally decoupled processes.
In contrast,
Klein et al. [1991] found a strong correlation between upwelling
temperature and
variations in major and moderately incompatible trace elements observed in
MORB from
Australian-Antarctic Discordance (AAD). These authors also found that the
highly
incompatible trace elements and isotopes appear to be decoupled from the
major and
moderately compatible trace elements. Pyle et al. [1992] presented
new Sr, Nd, and
Pb isotopic data that confirmed the presence of a boundary between `Indian'
type and
`Pacific' type MORB mantle beneath the AAD, and used the isotopic variations
to constrain
the westward migration of the Pacific mantle into the AAD. Large variations
in abundance
ratios of incompatible elements at similar MgO contents observed in basalts
from the AMAR
(ALVIN mid-Atlantic Ridge) axial valleys on the mid-Atlantic Ridge (MAR) are
interpreted
as evidence for mixing of magmas that formed by very different extents of
melting in the
mantle [ Frey et al., 1993]. This interpretation requires that
parental magmas of
widely different extents of melting are sampled from the same melting regime
directly
beneath a given ridge segment and thus, that a large, long-lived magma
chamber was not
present during eruption of the AMAR lavas. Batiza and Niu [1992]
conducted detailed
sampling of MORB from the EPR between 9
N and 9
51
N. They
found that major
and trace element data favored derivation of the magma compositions from a
single parental
composition by low pressure crystallization of the minerals olivine,
plagioclase and
clinopyroxene, although the lavas were erupted with only plagioclase as a
phenocryst
phase. They resolved the compositional and petrographic observations by
suggesting that
the mafic phases settled due to gravitational forces and the plagioclase
floated. In
addition they inferred that a single parental magma seemed to supply melts
to the axial
magma chamber along the entire 60 km segment of the EPR, suggesting that
central supply
injection sites are widely spaced, and that the axial magma chamber was
continuous along
the ridge.
Mahoney et al. [1992] suggested that the origin of the 
Pb
isotopic
signatures of MORB throughout the Indian Ocean could be related to the
initiation of a
more than 4400-km-long band of juxtaposed plume heads beneath the nearly
stationary
lithosphere of prebreakup Gondwana. White [1993] linked the variation
in the
U/
Pb ratio observed in MORB sampled from different ocean
basins to open
system evolution of the depleted upper mantle, suggesting that >10% of the
observed
mantle plume flux is required to mix with the depleted MORB mantle to supply
the required
flux of Pb. Mahoney et al. [1994] found a decoupling in the spatial
patterns of
trace element and isotopic enrichment for the superfast southern EPR that
appears to be
unique among the ocean ridge system. Salters and Hart [1991]
significantly expanded
the Lu-Hf isotopic data set for MORB and proposed that the Hf and Nd
isotopic systematics
of many MORB could only be explained if garnet was a residual phase during
melting. As
garnet is only stable in the mantle at pressures greater than 
25 kbar,
melting in the
presence of garnet has to occur at depths greater than 
80 km. This
controversial
hypothesis has become a central point of debate in current discussions of
MORB genesis.
Geochemical variations in MORB sampled from tectonically complex ridge
settings have been
reported for the Gulf of Aden, the Tuzo Wilson Volcanic Field (TWVF), and
the southern end
of the Pacific-East Pacific Rise. Schilling et al. [1992] use the
rare earth
element and Nd-Sr-Pb isotopic compositional profile of MORB sampled from the
Sheba Ridge
axis in the Gulf of Aden to constrain the interaction of the head of a
starting mantle
plume with continental lithosphere and an ocean basin in an early stage of
development.
Allan et al. [1993] identified alkaline volcanics in the TWVF which
are distinctly
different from MORB in their major and trace element characteristics. These
authors
suggested that in contrast to current wisdom which states that the TWFV is
either a site
of seafloor spreading or a hotspot/mantle plume, their data are consistent
with other
geophysical data in suggesting that the TWVF represents `leaky transform'
volcanism in an
oceanic setting. Lonsdale et al. [1992] characterized the triple
junction at 2
N on the EPR as a ridge-ridge-ridge junction, and
found that the MORB erupted there, like those erupted at the similar
Pacific-Nazca-Galapagos junction, are slightly enriched in incompatible
elements relative to lavas on adjacent segments of the EPR axis.
Exciting progress has been made in the study of temporal variations of the
magmatic
processes that create the oceanic crust. In contrast to the view that the
generation of
the oceanic crust is a steady state process producing MORB of essentially
constant
composition through time, detailed studies conducted at the segment
lengthscale have
linked patterns of compositional variation in MORB with spatial and temporal
variability
at the EPR [ Reynolds et al,. 1992], and at the southern Juan de Fuca
Ridge [ Smith et al., 1994]. In addition, significant progress has been
made in the dating of the very young basalts that erupt at ocean ridges.
Goldstein et al. [1991] used 
U-
Th systematics to date
axial and off-axis MORB from the Juan de Fuca and Gorda ridges, and showed
that the spreading rates inferred from the U-Th dates are consistent with
paleomagnetic spreading rates. Preliminary measurements of
Ra-
Th disequilibrium in MORB glasses from the
same region were shown to be magmatic in origin and used by
Volpe and Goldstein [1993] to quantify volcanic episodicity at
ocean ridges. Goldstein et al. [1994] used 
U-
Th and
U-
Pa ages (the technique is described in Goldstein
et al. [1993]) for basalts to quantify the spatial extent of young
volcanism and crustal accretion at 9
31
N on
the EPR. They found anomalously young ages for MORB relative
to ages inferred from spreading rates and distance from the axis,
and inferred from the young ages that most of the dated basalts were
actually erupted up to 4 km off-axis. Rubin et al. [1994]
present a new chronometer based on 
Po-
Pb radioactive
disequilibrium, which
allows the dating of glassy eruption products within a few years of their
eruption.