The low-temperature geothermal field of Nea Kessani, located in NE Gre
ece, is characterized by a thermal reservoir made up of arkosic sandst
ones. The temperature distribution at depth, inferred from exploratory
and productive wells, indicates that hot fluids rising from depth ent
er the arkosic reservoir in a restricted area of the field and flow to
wards local thermal springs. Well production tests have revealed the p
resence of hydrogeological boundaries within the arkosic reservoir. Th
e geochemical characteristics of the thermal waters, which have an Na-
Cl/HCO3 composition and salinity varying between 5 and 6 g/L, indicate
that these waters undergo conductive cooling within the reservoir. No
admixture of waters from the aquifers in the cover has been observed.
The slight chemical differences existing between the thermal waters a
re probably caused by CO2, which represents about two thirds by volume
of the discharged fluid. This CO2, as indicated by its isotopic compo
sition, could originate from decomposition of marbles of the Paleozoic
basement underlying the arkosic reservoir and may also affect the iso
topic composition of the thermal waters, which exhibit an interesting
positive oxygen shift. However, such a shift could also be the result
of water-rock exchange processes at low temperatures, since the water
feeding the field comes from a regional circulation which, as indicate
d by its deuterium content, has recharge areas on the Rhodope Chain. A
lternatively, the shift could be attributed to the contribution of a d
eep-seated high-temperature geothermal reservoir, but at present there
is no evidence of high-temperature resources in the region. A maximum
temperature of 110 degrees C has been estimated by quartz geothermome
try. The physical, chemical and hydrogeological data available so far
have permitted us to formulate a fluid circulation model for the Nea K
essani geothermal field.