The results of Hf isotopic analysis of peridotites are presented. Deve
lopment of a hot-SIMS technique for Hf isotope analysis has made this
possible at concentration levels that were previously prohibitively lo
w. Hf-176/Hf-177 ratios in abyssal peridotites and in two xenoliths fr
om the subcontinental lithosphere fall within the range observed for p
resent-day oceanic basalts. Hf-176/Hf-177 ratios in anhydrous spinel l
herzolites from Salt Lake Crater, Hawaii, however, range to extremely
radiogenic values, although Nd-143/Nd-144 is within the range of prese
nt-day MORBs. These high Hf-176/Hf-177 ratios (epsilon(Hf) up to 76) a
re well outside the range of oceanic volcanics and indicate that perid
otites such as these cannot have contributed significantly to Hawaiian
volcanism. The high Hf-176/Hf-177, combined with the enriched trace e
lement characteristics of the Salt Lake Crater peridotites may be expl
ained by either metasomatism of a depleted peridotite by a melt which
underwent extensive re-equilibration with material similar to the subo
ceanic lithosphere beneath Hawaii, or by ancient melt depletion (> 1 G
a) and recent enrichment of material stored in the sublithospheric man
tle. The good correlation between Hf and Nd isotopes in OIBs indicates
that the OIB source is not influenced by the high Hf-176/Hf-177 type
mantle identified in the Salt Lake Crater xenoliths. In contrast, the
lack of correlation between Hf and Nd isotopes in MORE can be explaine
d by pollution of the MORE reservoir with small amounts of this high-f
ield-strength-element-depleted, high Hf-176/Hf-177, lherzolitic materi
al.