Conditions and timing of quartz cementation in Brent reservoirs, Hild Field, North Sea: constraints from fluid inclusions and SIMS oxygen isotope microanalysis
Jp. Girard et al., Conditions and timing of quartz cementation in Brent reservoirs, Hild Field, North Sea: constraints from fluid inclusions and SIMS oxygen isotope microanalysis, CHEM GEOL, 176(1-4), 2001, pp. 73-92
The conditions and timing of quartz cementation in the Brent sandstones in
the Hild Field, Norwegian North Sea, were constrained on the basis of oxyge
n isotope microanalysis and fluid inclusion microthermometry combined with
optical and cathodoluminescence (CL) microscopy studies. Samples of the Tar
bert and the Ness Formations were investigated in three different wells, pr
esently lying at 3.8-4.3 km subsea and at 140-155 degreesC,
Quartz cement is present in all wells. Abundance varies from 3% to 26%. and
tends to increase with depth of burial. Two distinct, separate episodes of
quartz cementation, referred to as Q1 and Q2, are readily distinguished by
CL microscopy. The two episodes are also recognized in the bimodal distrib
ution of fluid inclusion temperatures and oxygen isotope microanalyses.
The data indicate that Q1 quartz formed in the Early Tertiary (65-35 Ma) at
95-110 degreesC acid 2.3-3.0 km burial depth, and that Q2 mainly precipita
ted in the Oligocene-Miocene (40-10 Ma) at 125-135 degreesC acid 3.1-3.7 km
. Q1 quartz precipitation follows the onset of overpressuring in the reserv
oir, while precipitation of Q2 seems to slightly precede and accompany the
main phase of oil filling (35-10 Ma). Secondary ion mass spectrometry (SIMS
) oxygen isotope microanalyses yield delta O-18 delta O-18 values ranging f
rom 17 parts per thousand to 25 parts per thousand, averaging 23 +/- 2 part
s per thousand for Q1 and 19.5 +/- 1.5 parts per thousand for Q2. Calculate
d delta O-18 values of quartz-forming waters are similar for Q1 and Q2, ran
ging from 1 parts per thousand to 3 parts per thousand, and are similar to
the delta O-18 value (approximate to 2 parts per thousand) of present-day f
ormation water in the reservoir.
Quartz cementation in the Brent reservoir of the Hild Field occurred during
deep burial, at high temperature, from evolved O-18-rich basinal water mos
t likely derived from the Viking Graben. Two episodes of enhanced quartz pr
ecipitation are recorded around 100 degreesC and 130 degreesC. No evidence
was found for any significant contribution of O-18-depleted Jurassic meteor
ic water and/or low temperature precipitation of quartz cement. (C) 2001 El
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