The first report of synthetic diamond involved a high-pressure high-te
mperature (HPHT) process in which diamond was the thermodynamically st
able phase(1). Subsequent attempts to make diamond at less extreme con
ditions culminated in the rapid growth of diamond films by chemical va
pour deposition(2,3). But the question of whether diamond might be gro
wn in hydrothermal conditions mimicking those under which it is formed
in the Earth has been long debated(4-6). It seems reasonable to suppo
se that metals might play a catalytic or solubilizing role in this con
text, given their role in the HPHT method(1), in a recent low-pressure
solid-state synthetic approach(7) and in the recrystallization of dia
mond in the Ni-NaOH-C system(8). Hydrothermal synthesis of diamond has
been explored at some length(9-13), but with equivocal results. Here
we report evidence from spectroscopic, diffraction and microscopic tec
hniques which suggest that aggregates, tens of micrometres in size, of
small diamond crystals can be grown in a hydrothermal environment fro
m a mixture of carbon, water and metal (usually pure nickel). Cruciall
y, we have been able to distinguish new diamond from the diamond seeds
added to nucleate new growth.