GEOCHEMISTRY%20OF%20GEOTHERMAL%20SYSTEMS

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GEOCHEMISTRY%20OF%20GEOTHERMAL%20SYSTEMS

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Title: GEOCHEMISTRY%20OF%20GEOTHERMAL%20SYSTEMS

1
GEOCHEMISTRY OFGEOTHERMAL SYSTEMS
2
WATER CHEMISTRY

Chemical composition of waters is expressed in
terms of major anion and cation contents.
Major Cations Na, K, Ca, Mg
Major Anions HCO3- (or CO3), Cl-, SO4
HCO3- ? dominant in neutral conditions
CO3 ? dominant in alkaline (pHgt8) conditions
H2CO3 ? dominant in acidic conditions
Also dissolved silica (SiO2) in neutral form
as a major constituent
Minor constituents B, F, Li, Sr, ...

3
WATER CHEMISTRY

concentration of chemical constituents are
expressed in units of
mg/l (ppmparts per million)
(mg/l is the preferred unit)
Molality
Molality no. of moles / kg of solvent
No.of moles (mg/l10-3) / formula weight

4
WATER CHEMISTRY

Errors associated with water analyses are
expressed in terms of CBE (Charge Balance Error)
CBE () ?( ?z x mc - ?z x ma ) / (?z x mc
?z x ma )? 100
where,
mc is the molality of cation
ma is the molality of anion
z is the charge
If CBE ? 5, the results are appropriate to use
in any kind of interpretation

5
The constituents encountered in geothermal fluids

TRACERS
Chemically inert, non-reactive, conservative
constituents
(once added to the fluid phase, remain unchanged
allowing their origins to be traced back to their
source component - used to infer about the source
characteristics)
e.g. He, Ar (noble gases), Cl, B, Li, Rb, Cs,
N2
GEOINDICATORS
Chemically reactive, non-conservative species
(respond to changes in environment - used to
infer about the physico-chemical processes during
the ascent of water to surface, also used in
geothermometry applications)
e.g. Na, K, Mg, Ca, SiO2

6
WATER CHEMISTRY

In this chapter, the main emphasis will be placed
on the use of water chemistry in the
determination of
underground (reservoir) temperatures
geothermometers
boiling and mixing relations (subsurface
physico-chemical processes)

7
HYDROTHERMAL REACTIONS

The composition of geothermal fluids are
controlled by temperature-dependent reactions
between minerals and fluids
The factors affecting the formation of
hydrothermal minerals are
temperature
pressure
rock type
permeability
fluid composition
duration of activity

The effect of rock type --- most pronounced at
low temperatures insignificant above 280?C
Above 280?C and at least as high as 350?C, the
typical stable mineral assemblages (in active
geothermal systems) are independent of rock type
and include
ALBITE, K-FELDSPAR, CHLORITE, Fe-EPIDOTE,
CALCITE, QUARTZ, ILLITE PYRITE
At lower temperatures, ZEOLITES and CLAY
MINERALS are found.
At low permeabilities equilibrium between rocks
and fluids is seldom achieved.
When permeabilities are relatively high and water
residence times are long (months to years), water
rock should reach chemical equilibrium.

9
At equilibrium, ratios of cations in solution are
controlled by temperature-dependent exchange
reactions such as NaAlSi3O8 (albite) K
KAlSi3O8 (K-felds.) Na
Keq. ? Na? / ? K? Hydrogen ion activity
(pH) is controlled by hydrolysis reactions, such
as 3 KAlSi3O8 (K-felds.) 2 H K
Al3Si3O10(OH)2 (K-mica) 6SiO2 2 K Keq.
? K? / ? H? where, Keq. equilibrium
constant, square brackets indicate activities of
dissolved species (activity is unity for pure
solid phases)
10
ESTIMATION OF RESERVOIR TEMPERATURES

The evaluation of the reservoir temperatures for
geothermal systems is made in terms of
GEOTHERMOMETRY APPLICATIONS

11
GEOTHERMOMETRY APPLICATIONS
12
GEOTHERMOMETRY APPLICATIONS

One of the major tools for the ?
exploration development
of geothermal resources

13
GEOTHERMOMETRY

estimation of reservoir (subsurface) temperatures
using
Chemical isotopic composition of surface
discharges from
wells and/or
natural springs/fumaroles

14
GEOTHERMOMETERS

CHEMICAL GEOTHERMOMETERS
utilize the chemical composition
silica and major cation contents of water
discharges
gas concentrations or relative abundances of
gaseous components in steam discharges
ISOTOPIC GEOTHERMOMETERS
based on the isotope exchange reactions between
various phases (water, gas, mineral) in
geothermal systems

15
Focus of the Course

CHEMICAL GEOTHERMOMETERS
As applied to water discharges
PART I. Basic Principles Types
PART II. Examples/Problems

16
CHEMICAL GEOTHEROMOMETERS

PART I. Basic Principles Types

17
BASIC PRINCIPLES

Chemical Geothermometers are
developed on the basis of temperature dependent
chemical equilibrium between the water and the
minerals at the deep reservoir conditions
based on the assumption that the water preserves
its chemical composition during its ascent from
the reservoir to the surface

18
BASIC PRINCIPLES

Studies of well discharge chemistry and
alteration mineralogy
the presence of equilibrium in several geothermal
fields
the assumption of equilibrium is valid

19
BASIC PRINCIPLES

Assumption of the preservation of water chemistry
may not always hold
Because the water composition may be affected
by processes such as
cooling
mixing with waters from different reservoirs.

20
BASIC PRINCIPLES

Cooling during ascent from reservoir to surface
CONDUCTIVE
ADIABATIC

21
BASIC PRINCIPLES

CONDUCTIVE Cooling
Heat loss while travelling through cooler rocks
ADIABATIC Cooling
Boiling because of decreasing hydrostatic head

22
BASIC PRINCIPLES

Conductive cooling
does not by itself change the composition of the
water
but may affect its degree of saturation with
respect to several minerals
thus, it may bring about a modification in the
chemical composition of the water by mineral
dissolution or precipitation

23
BASIC PRINCIPLES

Adiabatic cooling (Cooling by boiling)
causes changes in the composition of ascending
water
these changes include
degassing, and hence
the increase in the solute content as a result of
steam loss.

24
BASIC PRINCIPLES

MIXING
affects chemical composition
since the solubility of most of the compounds in
waters increases with increasing temperature,
mixing with cold groundwater results in the
dilution of geothermal water

Geothermometry applications are not simply
inserting values into specific geothermometry
equations.
Interpretation of temperatures obtained from
geothermometry equations requires a sound
understanding of the chemical processes involved
in geothermal systems.
The main task of geochemist is to verify or
disprove the validity of assumptions made in
using specific geothermometers in specific fields.

26
TYPES OF CHEMICAL GEOTHERMOMETERS

SILICA GEOTHERMOMETERS
CATION GEOTHERMOMETERS (Alkali Geothermometers)

27
SILICA GEOTHERMOMETERS

based on the
experimentally determined
temperature dependent
variation in the solubility of silica in water
Since silica can occur in various forms in
geothermal fields (such as quartz, crystobalite,
chalcedony, amorphous silica) different silica
geothermometers have been developed by different
workers

28
SILICA GEOTHERMOMETERS
Geothermometer Equation Reference
Quartz-no steam loss T 1309 / (5.19 log C) - 273.15 Fournier (1977)
Quartz-maximum steam loss at 100 oC T 1522 / (5.75 - log C) - 273.15 Fournier (1977)
Quartz T 42.198 0.28831C - 3.6686 x 10-4 C2 3.1665 x 10-7 C3 77.034 log C Fournier and Potter (1982)
Quartz T 53.500 0.11236C - 0.5559 x 10-4 C2 0.1772 x 10-7 C3 88.390 log C Arnorsson (1985) based on Fournier and Potter (1982)
Chalcedony T 1032 / (4.69 - log C) - 273.15 Fournier (1977)
Chalcedony T 1112 / (4.91 - log C) - 273.15 Arnorsson et al. (1983)
Alpha-Cristobalite T 1000 / (4.78 - log C) - 273.15 Fournier (1977)
Opal-CT (Beta-Cristobalite) T 781 / (4.51 - log C) - 273.15 Fournier (1977)
Amorphous silica T 731 / (4.52 - log C) - 273.15 Fournier (1977)
29
SILICA GEOTHERMOMETERS

The followings should be considered
temperature range in which the equations are
valid
effects of steam separation
possible precipitation of silica
before sample collection
(during the travel of fluid to surface, due to
silica oversaturation)
after sample collection
(due to improper preservation of sample)
effects of pH on solubility of silica
possible mixing of hot water with cold water

30
SILICA GEOTHERMOMETERS

Temperature Range
silica geothermometers are valid for temperature
ranges up to 250 ?C
above 250?C, the equations depart drastically
from the experimentally determined solubility
curves

31
SILICA GEOTHERMOMETERSTemperature Range

Fig.1. Solubility of quartz (curve A) and
amorphous silica (curve C) as a function of
temperature at the vapour pressure of the
solution. Curve B shows the amount of silica that
would be in solution after an initially
quartz-saturated solution cooled adiabatically to
100 ?C without any precipitation of silica (from
Fournier and Rowe, 1966, and Truesdell and
Fournier, 1976).
At low T (?C) ?
qtz less soluble
amorph. silica more soluble
Silica solubility is controlled by amorphous
silica at low T (?C) quartz at high T (?C)

32
SILICA GEOTHERMOMETERSEffects of Steam Separation

Boiling ? Steam Separation
volume of residual liquid?
Concentration in liquid?
Temperature Estimate?
e.g.
T 1309 / (5.19 log C) - 273.15
C SiO2 in ppm
increase in C (SiO2 in water gt SiO2 in reservoir)
decrease in denominator of the equation
increase in T
for boiling springs
boiling-corrected geothermometers
(i.e. Quartz-max. steam loss)

33
SILICA GEOTHERMOMETERSSilica Precipitation

SiO2 ?
Temperature Estimate?
e.g.
T 1309 / (5.19 log C) - 273.15
C SiO2 in ppm
decrease in C (SiO2 in water lt SiO2 in reservoir)
increase in denominator
decrease in T

34
SILICA GEOTHERMOMETERSEffect of pH

Fig. 2. Calculated effect of pH upon the
solubility of quartz at various temperatures from
25 ?C to 300 ?C , using experimental data of
Seward (1974). The dashed curve shows the pH
required at various temperatures to achieve a 10
increase in quartz solubility compared to the
solubility at pH7.0 (from Fournier, 1981).
pH ?
Dissolved SiO2 ? (for pHgt7.6)
Temperature Estimate?
e.g.
T 1309 / (5.19 log C) - 273.15
C SiO2 in ppm
increase in C
decrease in denominator of the equation
increase in T

35
SILICA GEOTHERMOMETERSEffect of Mixing

Hot-Water ? High SiO2 content
Cold-Water ? Low SiO2 content
(Temperature ? Silica solubility ?)
Mixing (of hot-water with cold-water)
Temperature?
SiO2 ?
Temperature Estimate ?
e.g.
T 1309 / (5.19 log C) - 273.15
C SiO2 in ppm
decrease in C
increase in denominator of the equation
decrease in T

36
SILICA GEOTHERMOMETERS

Process Reservoir Temperature
Steam Separation ? Overestimated
Silica Precipitation ? Underestimated
Increase in pH ? Overestimated
Mixing with cold water ? Underestimated

37
CATION GEOTHERMOMETERS (Alkali Geothermometers)

based on the partitioning of alkalies between
solid and liquid phases
e.g. K Na-feldspar Na K-feldspar
majority of are empirically developed
geothermometers
Na/K geothermometer
Na-K-Ca geothermometer
Na-K-Ca-Mg geothermometer
Others (Na-Li, K-Mg, ..)

38
CATION GEOTHERMOMETERSNa/K Geothermometer

Fig.3. Na/K atomic ratios of well discharges
plotted at measured downhole temperatures. Curve
A is the least square fit of the data points
above 80 ?C. Curve B is another empirical curve
(from Truesdell, 1976). Curves C and D show the
approximate locations of the low
albite-microcline and high albite-sanidine lines
derived from thermodynamic data (from Fournier,
1981).

39
CATION GEOTHERMOMETERSNa/K Geothermometer
Geotherm. Equations Reference
Na-K T855.6/(0.857log(Na/K))-273.15 Truesdell (1976)
Na-K T833/(0.780log(Na/K))-273.15 Tonani (1980)
Na-K T933/(0.993log (Na/K))-273.15 (25-250 oC) Arnorsson et al. (1983)
Na-K T1319/(1.699log(Na/K))-273.15 (250-350 oC) Arnorsson et al. (1983)
Na-K T1217/(1.483log(Na/K))-273.15 Fournier (1979)
Na-K T1178/(1.470log (Na/K))-273.15 Nieva and Nieva (1987)
Na-K T1390/(1.750log(Na/K))-273.15 Giggenbach (1988)
40
CATION GEOTHERMOMETERSNa/K Geothermometer

gives good results for reservoir temperatures
above 180?C.
yields erraneous estimates for low temperature
waters
temperature-dependent exchange equilibrium
between feldspars and geothermal waters is not
attained at low temperatures and the Na/K ratio
in these waters are governed by leaching rather
than chemical equilibrium
yields unusually high estimates for waters having
high calcium contents

41
CATION GEOTHERMOMETERSNa-K-Ca Geothermometer
Geotherm. Equations Reference
Na-K-Ca T1647/ (log (Na/K) ? (log (?Ca/Na)2.06) 2.47) -273.15 a) if ?log?Ca/Na)2.06? lt 0, use ?1/3 and calculate T?C b) if ?log?Ca/Na)2.06? gt 0, use ?4/3 and calculate T?C c) if calculated T gt 100?C in (b), recalculate T?C using ?1/3 Fournier and Truesdell (1973)
42
CATION GEOTHERMOMETERSNa-K-Ca Geothermometer

Works well for CO2-rich or Ca-rich environments
provided that calcite was not deposited after the
water left the reservoir
in case of calcite precipitation
Ca ?
1647
T --------------------------------------------
------------- - 273.15
log (Na/K) ? (log (?Ca/Na)2.06) 2.47
Decrease in Ca concentration (Ca in water lt Ca
in reservoir)
decrease in denominator of the equation
increase in T
For waters with high Mg contents, Na-K-Ca
geothermometer yields erraneous results. For
these waters, Mg correction is necessary

43
CATION GEOTHERMOMETERSNa-K-Ca-Mg Geothermometer
Geotherm. Equations Reference
Na-K-Ca-Mg T TNa-K-Ca - ?tMgoC R (Mg / Mg 0.61Ca 0.31K) x 100 if R from 1.5 to 5 ?tMgoC -1.03 59.971 log R 145.05 (log R)2 36711 (log R)2 / T - 1.67 x 107 log R / T2 if R from 5 to 50 ?tMgoC10.66-4.7415 log R325.87(log R)2-1.032x105(log R)2/T-1.968x107(log R)3/T2 Note Do not apply a Mg correction if ?tMg is negative or Rlt1.5. If Rgt50, assume a temperature measured spring temperature. T is Na-K-Ca geothermometer temperature in Kelvin Fournier and Potter (1979)
44
CATION GEOTHERMOMETERSNa-K-Ca-Mg Geothermometer

Fig. 4. Graph for estimating the magnesium
temperature correction to be subtracted from
Na-K-Ca calculated temperature (from Fournier,
1981)
R (Mg/Mg 0.61Ca 0.31K)x100

45
UNDERGROUND MIXING OF HOT AND COLD WATERS

Recognition of Mixed Waters
Mixing of hot ascending waters with cold waters
at shallow depths is common.
Mixing also occurs deep in hydrothermal systems.
The effects of mixing on geothermometers is
already discussed in previous section.
Where all the waters reaching surface are mixed
waters, recognition of mixing can be difficult.
The recognition of mixing is especially difficult
if water-rock re-equilibration occurred after
mixing (complete or partial re-equilibration is
more likely if the temperatures after mixing is
well above 110 to 150 ?C, or if mixing takes
place in aquifers with long residence times).

46
UNDERGROUND MIXING OF HOT AND COLD WATERS

Some indications of mixing are as follows
systematic variations of spring compositions and
measured temperatures,
variations in oxygen or hydrogen isotopes,
variations in ratios of relatively conservative
elements that do not precipitate from solution
during movement of water through rock (e.g. Cl/B
ratios).

47
SILICA-ENTHALPY MIXING MODEL

Dissolved silica content of mixed waters can be
used to determine the temperature of hot-water
component .
Dissolved silica is plotted against enthalpy of
liquid water.
Although temperature is the measured property,
and enthalphy is a derived property, enthalpy is
used as a coordinate rather than temperature.
This is because the combined heat contents of two
waters are conserved when those waters are mixed,
but the combined temperatures are not.
The enthalpy values are obtained from steam
tables.

48
SILICA-ENTHALPY MIXING MODEL

Fig. 5. Dissolved silica-enthalpy diagram
showing procedure for calculating the initial
enthalpy (and hence the reservoir temperature) of
a high temperature water that has mixed with a
low temperature water (from Fournier, 1981)

49
SILICA-ENTHALPY MIXING MODEL

A non-thermal component
(cold water)
B, D mixed, warm water
springs
C hot water component at
reservoir conditions
(assuming no steam
separation before mixing)
E hot water component at
reservoir conditions
(assuming steam separation
before mixing)
Boiling
T 100 ?C
Enthalpy 419 J/g

50
SILICA-ENTHALPY MIXING MODELSteam Fraction did
not separate before mixing

The sample points are plotted.
A straight line is drawn from the point
representing the non-thermal component of the
mixed water (i.e. the point with the lowest
temperature and the lowest silica content point
A in Fig.), through the mixed water warm springs
(points B and D in Fig.).
The intersection of this line with the qtz
solubility curve (point C in Fig.) gives the
enthalpy of the hot-water component (at reservoir
conditions).
From the steam table, the temperature
corresponding to this enthalpy value is obtained
as the reservoir temperature of the hot-water
component.

51
SILICA-ENTHALPY MIXING MODELSteam separation
occurs before mixing

The enthalpy at the boling temperature (100?C) is
obtained from the steam tables (which is 419 j/g)
A vertical line is drawn from the enthalpy value
of 419 j/g
From the inetrsection point of this line with the
mixing line (Line AD), a horizantal line (DE) is
drawn.
The intersection of line DE with the solubility
curve for maximum steam loss (point E) gives the
enthalpy of the hot-water component.
From the steam tables, the reservoir temperature
of the hot-water component is determined.

52
SILICA-ENTHALPY MIXING MODEL

In order for the silica mixing model to give
accurate results, it is vital that no conductive
cooling occurred after mixing. If conductive
cooling occurred after mixing, then the
calculated temperatures will be too high
(overestimated temperatures). This is because
the original points before conductive cooling
should lie to the right of the line AD (i.e.
towards the higher enthalpy values at the same
silica concentrations, as conductive cooling will
affect only the temperatures, not the silica
contents)
in this case, the intersection of mixing line
with the quartz solubility curve will give lower
enthalpy values (i.e lower temperatures) than
that obtained in case of conductive cooling.
in other words, the temperatures obtained in case
of conductive cooling will be higher than the
actual reservoir temperatures (i.e. if conductive
cooling occurred after mixing, the temperatures
will be overestimated)

53
SILICA-ENTHALPY MIXING MODEL

Another requirement for the use of
enthalpy-silica model is that no silica
deposition occurred before or after mixing. If
silica deposition occurred, the temperatures will
be underestimated. This is because
the original points before silica deposition
should be towards higher silica contents (at the
same enthalpy values)
in this case, the intersection point of mixing
line with the silica solubility curve will have
higher enthalpy values(higher temperatures) than
that obtained in case of silica deposition
in other words, the temperatures obtained in case
of no silica deposition will be higher than that
in case of silica deposition (i.e. the
temperatures will be underestimated in case of
silica deposition)

54
CHLORIDE-ENTHALPY MIXING MODEL

Fig.6. Enthalpy-chloride diagram for waters from
Yellowstone National Park. Small circles indicate
Geyser Hill-type waters and smal dots indicate
Black Sand-type waters (From Fournier, 1981).

55
CHLORIDE-ENTHALPY MIXING MODEL

ESTIMATION OF RESERVOIR
TEMPERATURE
Geyser Hill-type Waters
A maximum Cl content
B minimum Cl content
C minimum enthalpy at
the reservoir
Black Sand-type Waters
D maximum Cl content
E minimum Cl content
F minimum enthalpy at
the reservoir
Enthalpy of steam at 100 ?C
2676 J/g (Henley et al., 1984)

56
CHLORIDE-ENTHALPY MIXING MODEL

ORIGIN OF WATERS
N cold water component
C, F hot water components
F is more dilute slightly cooler than C
F can not be derived from C by process of mixing
between hot and cold water (point N), because any
mixture would lie on or close to line CN.
C and F are probably both related to a still
higher enthalpy water such as point G or H.

57
CHLORIDE-ENTHALPY MIXING MODEL

ORIGIN OF WATERS
water C could be related to water G by boiling
water C could also be related to water H
by conductive cooling
water F could be related to water G or water H by
mixing with cold water N

58
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59
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60
ISOTOPES IN GEOTHERMAL EXPLORATION
DEVELOPMENT
61
ISOTOPE STUDIES IN GEOTHERMAL SYSTEMS

At Exploration, Development and Exploitation
Stages
Most commonly used isotopes
Hydrogen (1H, 2H D, 3H)
Oxygen (18O, 16O)
Sulphur (32S, 34S)
Helium (3He, 4He)

62
ISOTOPE STUDIES IN GEOTHERMAL SYSTEMS

Geothermal Fluids
Sources
Source of fluids (meteoric, magmatic, ..)
Physico-chemical processes affecting the fluid
comosition
Water-rock interaction
Evaporation
Condensation
Source of components in fluids (mantle, crust,..)
Ages
(time between recharge-discharge,
recharge-sampling)
Temperatures (Geothermometry Applications)

63
Sources of Geothermal Fluids

Sources of Geothermal Fluids
H- O- Isotopes
Physico-chemical processes affecting the fluid
composition
H- O- Isotopes
Sources of components (elements, compounds) in
geothermal fluids
He-Isotopes (volatile elements)

64
Sources of Geothermal Fluids and
Physico-Chemical Processes

STABLE
H- O-ISOTOPES

65
Sources of Geothermal Fluids Stable H-
O-Isotopes

1H 99.9852
2H (D) 0.0148
D/H
16O 99.76
17O 0.04
18O 0.20
18O / 16O

66
Sources of Geothermal Fluids Stable H-
O-Isotopes

(D/H)sample-
(D/H)standard
? D (?) ----------------------------------- x
103
(D/H)standard
(18O/16O)sample-
(18O/16O)standard
? 18O (?) --------------------------------------
------ x 103
(18O/16O)standard
Standard Standard Mean Ocean Water
SMOW

67
Sources of Geothermal Fluids Stable H-
O-Isotopes

(D/H)sample- (D/H)SMOW
? D (?) ----------------------------------- x
103
(D/H)SMOW
(18O/16O)sample-
(18O/16O)SMOW
? 18O (?) --------------------------------------
------ x 103
(18O/16O)SMOW

68
Sources of Geothermal Fluids Stable H-
O-Isotopes

Sources of Natural Waters
Meteoric Water (rain, snow)
Sea Water
Fossil Waters (trapped in sediments in sedimanary
basins)
Magmatic Waters
Metamorphic Waters

69
Sources of Geothermal Fluids Stable H-
O-Isotopes
70
Sources of Geothermal Fluids Stable H-
O-Isotopes
71
Sources of Geothermal Fluids Stable H-
O-Isotopes
72
Sources of Geothermal Fluids Stable H-
O-Isotopes
73
Physico-Chemical ProcessesStable H- O-Isotopes

Latitute ?
dD? d18O?
Altitute from Sea level ?
dD? d18O?

74
Physico-Chemical ProcessesStable H- O-Isotopes

Aquifers recharged by precipitation from lower
altitutes ?higher dD - d18O values
Aquifers recharged by precipitation from higher
altitutes ?lower dD - d18O values
Mixing of waters from different aquifers

75
Physico-Chemical ProcessesStable H- O-Isotopes

Boiling and vapor separation ?
dD? d18O? in residual liquid
Possible subsurface boiling as a consequence of
pressure decrease (due to continuous exploitation
from production wells)

76
Monitoring Studies in Geothermal Exploitation

Any increase in dD - d18O values ?
due to sudden pressure drop in production
wells
?recharge from (other) aquifers fed by
precipitation from lower altitutes
?subsurface boiling and vapour separation

Aquifers recharged by precipitation from lower
altitutes ?higher dD - d18O
Aquifers recharged by precipitation from higher
altitutes ?lower dD - d18O
Boiling and vapor separation ?
dD? d18O? in residual liquid

77
Monitoring Studies in Geothermal Exploitation

Monitoring of isotope composition of geothermal
fluids during exploitation can lead to
determination of, and the development of
necessary precautions against
Decrease in enthalpy due to start of recharge
from cold, shallow aquifers, or
Scaling problems developed as a result of
subsurface boiling

78
(Scaling)

Vapour Separation
Volume of (residual) liquid ?
Concentration of dissolved components in liquid ?
Liquid will become oversaturated
Component (calcite, silica, etc.) will
precipitate
Scaling

79
Dating of Geothermal Fluids

3H- 3He-ISOTOPES

80
Dating of Geothermal Fluids

Time elapsed between Recharge-Discharge or
Recharge-Sampling points (subsurface residence
residence time)
3H method
3H-3He method

81
TRITIUM (3H)

3H radioactive isotope of Hydrogene (with a
short half-life)
3H forms
Reaction of 14N isotope (in the atmosphere) with
cosmic rays
147N n ? 31H 126C
Nuclear testing
3H concentration
Tritium Unit (TU)
1 TU 1 atom 3H / 1018 atom H
3H ? 3He ?
Half-life 12.26 year
Decay constant (?) 0.056 y-1

82
3H Dating Method

3H concentration level in the atmosphere has
shown large changes
In between 1950s and 1960s (before and after the
nuclear testing)
Particularly in the northern hemisphere
Before 1953 5-25 TU
In 1963 ?3000 TU

83
3H Dating Method

3H-concentration in groundwater lt 1.1 TU
Recharge by precipitations older than nuclear
testing
3H-concentration in groundwater gt 1.1 TU
Recharge by precipitations younger than nuclear
testing
NN0e-?t
3H0 (before 1963) ? 10 TU
3H 3H0e-?t
? 0.056 y-1
t 2003-1963 40 years
? 3H ? 1.1 TU

84
3H Dating Method

APPARENT AGE
3H 3H0e-?t
3H measured at sampling point
3H0 measured at recharge point
(assumed to be the initial tritium
concentration)
? 0.056 y-1
t apparent age

85
3H 3He Dating Method

3He 3H0 3H (D N0-N)
3H 3H0 e-?t (N N0e -?t)
3H0 3H e?t
3He 3H e?t - 3H 3H (e?t 1)
t 1/? ln (3He/3H 1)
3He 3H present-day concentrations measured
in water sample

86
Geothermometry Applications

Isotope Fractionation Temperature Dependent
Stable isotope compositions ?
utilized in Reservoir Temperature
estimation
Isotope geothermometers
Based on isotope exchange reactions between
phases in natural systems
(phases watre-gas, vapor-gas,
water-mineral.....)
Assumes reaction is at equilibrium at reservoir
conditions

87
Isotope Geothermometers

12CO2 13CH4 13CO2 12CH4 (CO2 gas - methane
gas)
CH3D H2O HDO CH4 (methane gas water
vapor)
HD H2O H2 HDO (H2 gas water vapor)

S16O4 H218O S18O4 H216O (dissolved
sulphate-water)
?
1000 ln ? (SO4 H2O) 2.88 x 106/T2 4.1 (T
degree Kelvin K )
88
Isotope Geothermometers

Regarding the relation between mineralization and
hydrothermal activities
Mineral Isotope Geothermometers
Based on the isotopic equilibrium between the
coeval mineral pairs
Most commonly used isotopes S-isotopes

89
Suphur (S)- Isotopes

32S 95.02
33S 0.75
34S 4.21
36S 0.02

(34S/32S)sample-
(34S/32S)std. ? 34S (?) ------------------------
-------------------- x 103
(34S/32S)sample Std. CD
S-isotope composition of troilite (FeS) phase in
Canyon Diablo Meteorite
90
S-Isotope Geothermometer