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Downward continuation of heat flow density data and thermal regime in Eastern Canada
Tectonophvsics, 194 (1991) 349-356 Elsevier Science Publishers
349
B.V., Amsterdam
Downward
continuation of heat flow density data and thermal regime in Eastern Canada Jean-Claude
Mareschal
Dhpartment des Sciences de la Terre and GEOTOP, UniuersitP du Quebec a Montrkal, Mont&al, Que. H3C 3P8, Canada (Received
January
2, 1990; revised version
accepted
March
26, 1990)
ABSTRACT Mareschal, J.C., 1991. Downward continuation Cermak and J.H. Sass (Editors), Forward 349-356.
of heat flow density data and thermal and Inverse Techniques in Geothermal
regime in Eastern Canada. Modelling. Tectonophysics,
In: V. 194:
Heat flow density (HFD) data from Eastern Canada were analyzed by downward continuation. The data cover parts of the Superior and Grenville provinces of the Canadian Shield, and parts of the Appalachian orogen. The downward continuation eliminates the effect of shallow crustal radiogenic heat production and better reveals differences in the thermal regime of deeper origin. The analysis shows that the deep heat flow beneath the Superior and Grenville provinces is low and the temperature in the lower crust is also low. The thermal regime of the crust changes markedly across a boundary that follows the St Lawrence River. Surface heat flow and heat production are markedly higher in the Appalachian Province. With much higher temperature and heat flow, the thermal regime in the Appalachian lower crust is also distinctly different from that of the shield. Temperature and heat flow increase eastward toward the Atlantic margin.
have been proposed
Introduction
relationship, The thermal all the major
regime tectonic,
of the lithosphere volcanic
crement
affects
D is often preferred
relationship
and metamorphic
that are compatible
but an exponential unaffected
by
with this
decrease because
with de-
it leaves the
differential
erosion
processes. Heat flow density (HFD) data provide the main constraint on the present thermal struc-
(Lachenbruch, 1970). This understanding has been recently questioned. The significance of the rela-
ture
tionship
of the
portant and
clues
lithosphere; about
the evolution
they
also
the conditions of the continental
contain
im-
port is considered
of formation
surements
lithosphere.
q=q,+AD In this relationship, the slope D is related to the thickness of the surficial heat producing layer and AD is understood as the contribution of the surficial heat sources to the heat flow; the intercept q,,, is interpreted as the deep contribution to the heat flow. Several models of heat source distribution Publishers
(Jaupart,
1983). Also, the mea-
production
in the superdeep
decreases with the tectonic age of a province (Polyak and Smirnov, 1968; Vitorello and Pollack,
et al., 1968).
0 1991 - Elsevier Science
of heat
heat trans-
well of the Kola peninsula (Arshavskaya et al., 1986) did not support the exponential model. It has been suggested that the average heat flow
The understanding of continental heat flow is based mostly on the linear relationship between the heat flow, q, and the heat production, A, in the crystalline rocks exposed at the surface (Roy
0040-1951/91/$03.50
is not so clear when horizontal
1980). It has also been proposed
that, at the time
of crustal
flow is equal
stabilization,
the heat
to
the present heat flow in young provinces, such as the Basin and Range. Analysis of the continental heat flow data shows that the average heat flow does not vary significantly between late Paleozoic and early Proterozoic provinces (Sclater et al., 1980; Morgan, 1985). The heat flow is higher in B.V
J.-C. MARESCHAL
350
younger
that are still affected
by tran-
the deep heat flow were obtained
it is lower for the Archean
cratons.
continuation
provinces
sient effects;
The low Archean concerns could
the oldest preserved
indicate
elements,
crust.
or a primary
Alternately,
an increase
tion of the shallow
crust.
It
their
crust is depleted
Ballard
is the result of early
feature
of the Archean
et al. (1987)
observed
in heat flow from the craton
the surrounding that
it
but it does not establish
or not this depletion
stabilization
because
continental
that the Archean
in radiogenic whether
heat flow is intriguing
mobile
heat flow is the result
of
the formation of a thick lithospheric root beneath the craton. The Canadian Shield, where a variety of terranes with distinct ages are juxtaposed, is an ideal region to investigate the importance of the geothermal
characteristics
Unfortunately,
for crustal
the distribution
stabilization.
of HFD
the
depth HFD
heat sources
is proportional variations
Mareschal strates
et al.,
that
that
to the wavelength
1989a).
same in the Grenville
the contribu-
and assume
(Mareschal
the character
that it changes
from downward
that include
The
et
al.,
analysis
of
1985; demon-
of the heat flow is the
and Superior
markedly
provinces,
but
in the Appalachians.
toward
belts. They have suggested
the early Archean
operators
data is
Downward continuation
The
method
potential
fields
of
of heat flow
downward
in geophysics
continuation was introduced
of by
Tsuboi (1939).
and Fuchida (1937, 1938) and Tsuboi In was developed and used mostly for
gravity
and magnetic
data by many
workers
(e.g.,
extremely uneven within and between the different geologic provinces of Eastern Canada. Jessop
Bullard and Cooper, 1948; Kreisel, 1949; Peters, 1949; Bott, 1967; Bodvarsson, 1971, 1973, among
et al. (1984) compiled all the data collected in Canada prior to 1983; this report included 27 sites from the Superior Province, 17 in the Canadian
others). Huestis (1979, 1980, 1981) considered the more general problem of inversion of heat flow data; he applied the method of Backus and Gil-
Appalachians, and only 5 sites from the Grenville Province; in addition fifteen sites were reported in
bert (1968) temperature
the platform sediments lying on Grenville ment (Southern Ontario and St-Lawrence
data.
baselow-
lands). Most of the recent additions to these HFD data are located in the Superior (Drury and Taylor, 1987) and Churchill provinces (Drury, 1985) or the Appalachians (Drury et al., 1987). Twenty-five new HFD and heat generation measurements from sites located in Quebec are reported by Mareschal et al. (1989b)
and
Pinet
et al. (in press);
measurements include twelve new sites Grenville Province. The HFD measured
these in the in the
Grenville by Mareschal et al. (1989b) is extremely low (22-30 mW m-’ after adjustment for postglacial climatic variations). These data thus suggest that the Grenville HFD is comparable to that of Archean crust with lower radiogenic heat production. The purpose of this paper is to report on an analysis of the thermal regime of Eastern Canada by downward continuation of the heat flow density data. The Fourier spectrum of the HFD was evaluated from all the data available in Eastern Canada. The temperature in the lower crust and
to infer lower distributions
These
results
were
and upper compatible generalized
bounds with
on the
by Huestis
(1984) who considered the effect of thermal conductivity variations on the temperature estimates. Brott et al. (1981) presented a downward continuation technique based on image theory which yields subsurface sources are present,
temperatures when no heat or permits an interpretation of
the source configuration. The distribution of radiogenic heat sources with and the mantle heat flow are often esti-
depth
mated by analyzing the spatial variations of the heat flow data (Roy et al., 1968; Lachenbruch, 1970). Fourier
transform
techniques
are conveni-
ent to analyze spatial variations of data and to downward continue potential fields, but they have seldom been used for heat flow because the data are usually too sparse to provide a good estimate of the spectrum. Mareschal et al. (1985, 1989a) have thus generalized the technique of Bodvarsson (1973) for downward continuation of the heat flow. They determine the Fourier components of the HFD. Assuming that the depth of the sources for each component is proportional to its wave-
DOWNWARD
length,
CONTINUATION
OF HEAT
they infer source
with the surface
HFD
By convention, defined
FLOW
AND
distributions
directly
THERMAL
REGIME,
transforms
as follows (e.g., Sneddon,
351
CANADA
(2) The heat sources
compatible
between
from the spectrum.
the Fourier
EAST
pair is
When
the heat
are uniformly
sources
given by the following al., 1989a): J-
dx dy
Y) = &lr,l_m,%? xexp[
k,>)
-i(k,x
+ k,y)]
In Fourier
transform
domain,
heat equation 1959):
is given
the equilibrium and
Jaeger,
1 is
T(k,,
the
z)=
k,, thermal
-Sk, K k,, z)
temperature T(k,,
distribution k,,
conductivity,
are the surface
z = 0), assumed
HFD q0(k,, ky). If there were no heat sources, form of the temperature would be given by: T(k,
T(j$, z) =
q,(k). mslnh(
T(k,
-smh(cu)
z) =
et
Ikjz
lk Id
q,(k).
exp(ar-
IklK
q(k,
z) = q,,(k)
q(k,
z) = -q,(k)
z) = hqo(x)
If the heat between
and
S(k,r, k,, z) is the Fourier transform of the heat source density at depth z. In geophysical applications, the heat sources are not known, and the only constraints on the ture
(Mareschal
lklz) Iklz>a _ Iklz
dk, dk,
by (Carslaw
a2
K
and the heat flow are
expressions
cosh( lk I z) sinh(a)
exp(a-
IkIt) (klz>a
T-k:-k; aZ where
on a
CQJ-cc
xexp[i(k,x+k,Y)]
f(X?
are concentrated
plane layer, the temperature
1972):
distributed
and the layer z = a/ I k (
the surface
tempera-
to be zero, the Fourier
distribution
temperature T(k,
z)=
sources
the surface spectrum
are uniformly is obtained
distributed
z = cu/ I % 1, the
and the plane
as:
l~~~k’~~~~l[l-exp(-lklz) ex (Y -exp(
-a)
sinh( 1X I z)]
Iklz
and trans-
at depth
z
xexp(-lklz)[cosh(cw)-l] Ik)z>a
sinh{ lklz}
In general, this expression transform because the Fourier Bodvarsson (1973) converge.
is not a Fourier integral does not proposed a long
wavelength approximation to continue downward potential fields to arbitrary depth; only the wavenumbers smaller than l/z are retained in the spectrum; larger wave numbers are considered to be part of the noise and are filtered out. Mareschal et al. (1985) considered short wavelengths to be related to the shallow heat sources and included them in the downward continued temperature and heat flow spectra. They examined two heat source distributions: (1) The heat sources are concentrated on the layer z=a/Ikl.
and the heat flow spectrum
-exp(-cr)
is given by:
cosh( lklz)]
Ik(z
4%
z>=4ow ex;;$: Xexp(-
1
(1 - casha)
lklz)
Iklz>a For the two distributions considered, the heat sources vary horizontally like an harmonic function of given wavenumber and are positive as well as negative. The undesirable negative values can be eliminated by adding a constant to the harmonic source distribution so that the heat sources are
J.-C. MARESCHAL
352
positive
everywhere.
must be removed ponent
This
constant
contribution
from the zero wavenumber
quencies
that are not resolved;
Fourier
com-
spectrum
Figure Thermal
that has been determined
used to interpolate
of the heat flow spectrum.
tinued
regime of Eastern Canada
i.e. the part of the
between
3 shows the temperature
to a depth
on a map of Eastern include ported
Canada
all the HFD between
values
44” N and
60 o W and 80 ’ W (Jessop Taylor,
1987; Drury
in Fig. 1. The data that
have
been
50” N and
et al., 1984; Drury
et al., 1987, Mareschal
and
the HFD
data
are irregularly
uted, the usual FFT technique cannot to determine the spectrum. Interpolating on a regular
grid would
smooth
temperature. beneath
be applied the HFD
out the data and
Province.
of November
trum
and the “warmer” cides geographically
they can be resolved
from closely
burg, 1976). This inversion is an undetermined problem as the number of frequencies in the spectrum is much larger than the number
of data. The
the
also be noted
that
crust
implies
6.2 Saguenay
25 1988 (North
earth-
et al., 1989).
The Grenville front does not appear to coincide with any boundary between different thermal provinces.
although
is low
Shield, including
in the lower
for the magnitude
alter the spectrum, and thus effectively eliminate the short wavelength components from the specspaced data points. The Fourier spectrum was thus determined by direct inversion (e.g., Olden-
It should
of
rather than ductile behavior. This is conwith the 29 km focal depth that has been
determined quake
estimate
It shows that the temperature
the low temperature brittle sistent
of the main
a precise
the entire Canadians
Grenville
et al.,
distrib-
and does not provide
con-
conduc-
to be 2.4 W m-’
Such a map is only indicative
trends
re-
between
1989b; Pinet et al., 1991). Figure 2 shows a contoured heat flow map of Eastern Canada. Because
K-‘.
data used in the study are displayed
downward
of 20 km. The thermal
tivity of the crust was assumed The HFD
can be
the data.
The
southeast;
temperature
the boundary
increases between
Appalachian with the
to increase
Figure 4 shows the temperature to 20 km when
the heat
the shield
Province coinSaint-Lawrence
River. The temperature continues ward the Atlantic margin. tinued
toward
the “cold”
downward sources
tocon-
are de-
frequencies that are retained are those that are well resolved by the data. The implicit assumption
termined from surface heat production measurements. It shows the same trends as in the previous
is that the Fourier
map,
spectrum
vanishes
for the fre-
but
with
higher
temperatures.
This
is be-
60” W_
SUPERIOR
Fig. 1. Map of the study area. Dots indicate
the location
of HFD measurements
for Holocene
climatic
sites. The values posted
variations.
are HFD (mW/m’)
adjusted
DOWNWARD
CONTINUATION
OF HEAT
FLOW
Fig, 2. Contoured
often
the basement
5 shows the HFD
REGIME,
EAST
the
measurements,
outcroping metavolcanic rocks and not on basement
underestimate
tion. Figure
THERMAL
353
CANADA
heat flow map of the study area. Contour
cause most of the heat production performed on metasedimentary
AND
heat
downward
or rocks, produc-
continued
lines are 5 mW mm2 apart.
Grenville
metamorphic
Province events
was
between
affected
by several
late Archean
(2650
Ma) and Grenvillian (1000 Ma) time (e.g., Doig, 1977). In the parautochtonous belt south of Grenville front, the high-grade rocks exposed have Archean
metamorphic
ages; paleopressures
in the
to a depth of 20 km. This operation has removed the effect of the shallow sources from the HFD. The trend is similar to that exhibited by the tem-
range 600-800 MPa have been determined (Indares and Martignole, 1989). In this part of the Grenville Province, the shallow crust consists of
perature
Archean
entire
field. The heat flow density shield is low. Apparently,
beneath
the
there is no ther-
rocks that formed
at lower crustal
depth.
The low heat flow is thus the result of depletion
of
mal boundary between the Superior and the Grenville provinces. This absence of contrast in HFD
radiogenic elements of these rocks of lower crustal origin. One could also conjecture that, if indeed an
has several implications.
It is now established
Archean
Fig. 3. Subsurface
map at 20 km depth.
was assumed
temperature
to be 2.4 W m-l
K-l.
that
The contour
“ tectonosphere”
lines are 50 o C apart.
The thermal
The heat sources were assumed to vary as a harmonic plane z = 0.2/k, where k is the wave number.
function
formed
conductivity
under
the cra-
of the upper crust
and to be concentrated
on the
J.-C. MARESCHAL
354
Fig. 4. Subsurface was assumed
temperature
map at 20 km depth.
to be 2.4 W mm’ K-‘.
The contour
The heat sources
uniformly
ton,
it extended
far into
the Grenville
extended
Prosug-
as far as the
Conclusions Because of the limited HFD data available in Eastern Canada, the tectonic immplications of the thermal regime of the Canadian Shield have not yet been
fully explored.
Downward
The thermal
from available
conductivity
heat production
of the upper
measurements
crust
and extend
to 10 km.
is one technique
Province,
beyond the present boundary of the Superior vince (i.e. the Grenville front). This analysis gests that it could have Saint-Lawrence River.
lines are 50 o C apart.
were determined
information
that
may help
from the HFD
The major difficulty
to derive
useful
data.
in such studies is to extract
this information from unevenly distributed data. In this study, the data were inverted to determine their Fourier spectrum. This technique effectively selects the wavelengths of the Fourier spectrum that the data satisfactorily resolve and disregards all other wavelengths. Implicitly, it assumes that the HFD spectrum can be extrapolated where no data are available. The analysis
continuation
of the thermal
to regions
regime of the crust
60%‘_
Fig. 5. Heat flow at a depth harmonic
of 20 km after removal function
of shallow
and to be concentrated
sources
contribution.
on the plane z = 0.2/k,
The heat sources
were assumed
where k is the wave number.
to vary as a
DOWNWARD
CONTINUATION
in eastern
Canada
the Provinces Archean
OF HEAT
shows
ent boundary cluded Grenville
extended
part
contains
the pres-
Province
M.J. and Taylor,
Can. J. Earth Drury,
in-
nature
Also,
the
133: l-14. Huestis,
in radio-
and temperature partly
values in the
the result
but they are mostly
are probably
related
of localized
of deeper
to higher
flow and transient effects opening of the Atlantic.
Appalachian
S.P., 1979. Extremal
reduced
associated
heat
with
Huestis,
The author
gratefully Sciences
S.P.,
the
Huestis,
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the corrresponding Earthquake
Res., in press. Polyak,
Tsuboi,
MARESCHAL
Pollack,
H.N.,
1980.
On
the variation
heat flow with age and the thermal
the continents.
J. Geophys.
Res., 85: 983-995.
evolution
of of
349
B.V., Amsterdam
Downward
continuation of heat flow density data and thermal regime in Eastern Canada Jean-Claude
Mareschal
Dhpartment des Sciences de la Terre and GEOTOP, UniuersitP du Quebec a Montrkal, Mont&al, Que. H3C 3P8, Canada (Received
January
2, 1990; revised version
accepted
March
26, 1990)
ABSTRACT Mareschal, J.C., 1991. Downward continuation Cermak and J.H. Sass (Editors), Forward 349-356.
of heat flow density data and thermal and Inverse Techniques in Geothermal
regime in Eastern Canada. Modelling. Tectonophysics,
In: V. 194:
Heat flow density (HFD) data from Eastern Canada were analyzed by downward continuation. The data cover parts of the Superior and Grenville provinces of the Canadian Shield, and parts of the Appalachian orogen. The downward continuation eliminates the effect of shallow crustal radiogenic heat production and better reveals differences in the thermal regime of deeper origin. The analysis shows that the deep heat flow beneath the Superior and Grenville provinces is low and the temperature in the lower crust is also low. The thermal regime of the crust changes markedly across a boundary that follows the St Lawrence River. Surface heat flow and heat production are markedly higher in the Appalachian Province. With much higher temperature and heat flow, the thermal regime in the Appalachian lower crust is also distinctly different from that of the shield. Temperature and heat flow increase eastward toward the Atlantic margin.
have been proposed
Introduction
relationship, The thermal all the major
regime tectonic,
of the lithosphere volcanic
crement
affects
D is often preferred
relationship
and metamorphic
that are compatible
but an exponential unaffected
by
with this
decrease because
with de-
it leaves the
differential
erosion
processes. Heat flow density (HFD) data provide the main constraint on the present thermal struc-
(Lachenbruch, 1970). This understanding has been recently questioned. The significance of the rela-
ture
tionship
of the
portant and
clues
lithosphere; about
the evolution
they
also
the conditions of the continental
contain
im-
port is considered
of formation
surements
lithosphere.
q=q,+AD In this relationship, the slope D is related to the thickness of the surficial heat producing layer and AD is understood as the contribution of the surficial heat sources to the heat flow; the intercept q,,, is interpreted as the deep contribution to the heat flow. Several models of heat source distribution Publishers
(Jaupart,
1983). Also, the mea-
production
in the superdeep
decreases with the tectonic age of a province (Polyak and Smirnov, 1968; Vitorello and Pollack,
et al., 1968).
0 1991 - Elsevier Science
of heat
heat trans-
well of the Kola peninsula (Arshavskaya et al., 1986) did not support the exponential model. It has been suggested that the average heat flow
The understanding of continental heat flow is based mostly on the linear relationship between the heat flow, q, and the heat production, A, in the crystalline rocks exposed at the surface (Roy
0040-1951/91/$03.50
is not so clear when horizontal
1980). It has also been proposed
that, at the time
of crustal
flow is equal
stabilization,
the heat
to
the present heat flow in young provinces, such as the Basin and Range. Analysis of the continental heat flow data shows that the average heat flow does not vary significantly between late Paleozoic and early Proterozoic provinces (Sclater et al., 1980; Morgan, 1985). The heat flow is higher in B.V
J.-C. MARESCHAL
350
younger
that are still affected
by tran-
the deep heat flow were obtained
it is lower for the Archean
cratons.
continuation
provinces
sient effects;
The low Archean concerns could
the oldest preserved
indicate
elements,
crust.
or a primary
Alternately,
an increase
tion of the shallow
crust.
It
their
crust is depleted
Ballard
is the result of early
feature
of the Archean
et al. (1987)
observed
in heat flow from the craton
the surrounding that
it
but it does not establish
or not this depletion
stabilization
because
continental
that the Archean
in radiogenic whether
heat flow is intriguing
mobile
heat flow is the result
of
the formation of a thick lithospheric root beneath the craton. The Canadian Shield, where a variety of terranes with distinct ages are juxtaposed, is an ideal region to investigate the importance of the geothermal
characteristics
Unfortunately,
for crustal
the distribution
stabilization.
of HFD
the
depth HFD
heat sources
is proportional variations
Mareschal strates
et al.,
that
that
to the wavelength
1989a).
same in the Grenville
the contribu-
and assume
(Mareschal
the character
that it changes
from downward
that include
The
et
al.,
analysis
of
1985; demon-
of the heat flow is the
and Superior
markedly
provinces,
but
in the Appalachians.
toward
belts. They have suggested
the early Archean
operators
data is
Downward continuation
The
method
potential
fields
of
of heat flow
downward
in geophysics
continuation was introduced
of by
Tsuboi (1939).
and Fuchida (1937, 1938) and Tsuboi In was developed and used mostly for
gravity
and magnetic
data by many
workers
(e.g.,
extremely uneven within and between the different geologic provinces of Eastern Canada. Jessop
Bullard and Cooper, 1948; Kreisel, 1949; Peters, 1949; Bott, 1967; Bodvarsson, 1971, 1973, among
et al. (1984) compiled all the data collected in Canada prior to 1983; this report included 27 sites from the Superior Province, 17 in the Canadian
others). Huestis (1979, 1980, 1981) considered the more general problem of inversion of heat flow data; he applied the method of Backus and Gil-
Appalachians, and only 5 sites from the Grenville Province; in addition fifteen sites were reported in
bert (1968) temperature
the platform sediments lying on Grenville ment (Southern Ontario and St-Lawrence
data.
baselow-
lands). Most of the recent additions to these HFD data are located in the Superior (Drury and Taylor, 1987) and Churchill provinces (Drury, 1985) or the Appalachians (Drury et al., 1987). Twenty-five new HFD and heat generation measurements from sites located in Quebec are reported by Mareschal et al. (1989b)
and
Pinet
et al. (in press);
measurements include twelve new sites Grenville Province. The HFD measured
these in the in the
Grenville by Mareschal et al. (1989b) is extremely low (22-30 mW m-’ after adjustment for postglacial climatic variations). These data thus suggest that the Grenville HFD is comparable to that of Archean crust with lower radiogenic heat production. The purpose of this paper is to report on an analysis of the thermal regime of Eastern Canada by downward continuation of the heat flow density data. The Fourier spectrum of the HFD was evaluated from all the data available in Eastern Canada. The temperature in the lower crust and
to infer lower distributions
These
results
were
and upper compatible generalized
bounds with
on the
by Huestis
(1984) who considered the effect of thermal conductivity variations on the temperature estimates. Brott et al. (1981) presented a downward continuation technique based on image theory which yields subsurface sources are present,
temperatures when no heat or permits an interpretation of
the source configuration. The distribution of radiogenic heat sources with and the mantle heat flow are often esti-
depth
mated by analyzing the spatial variations of the heat flow data (Roy et al., 1968; Lachenbruch, 1970). Fourier
transform
techniques
are conveni-
ent to analyze spatial variations of data and to downward continue potential fields, but they have seldom been used for heat flow because the data are usually too sparse to provide a good estimate of the spectrum. Mareschal et al. (1985, 1989a) have thus generalized the technique of Bodvarsson (1973) for downward continuation of the heat flow. They determine the Fourier components of the HFD. Assuming that the depth of the sources for each component is proportional to its wave-
DOWNWARD
length,
CONTINUATION
OF HEAT
they infer source
with the surface
HFD
By convention, defined
FLOW
AND
distributions
directly
THERMAL
REGIME,
transforms
as follows (e.g., Sneddon,
351
CANADA
(2) The heat sources
compatible
between
from the spectrum.
the Fourier
EAST
pair is
When
the heat
are uniformly
sources
given by the following al., 1989a): J-
dx dy
Y) = &lr,l_m,%? xexp[
k,>)
-i(k,x
+ k,y)]
In Fourier
transform
domain,
heat equation 1959):
is given
the equilibrium and
Jaeger,
1 is
T(k,,
the
z)=
k,, thermal
-Sk, K k,, z)
temperature T(k,,
distribution k,,
conductivity,
are the surface
z = 0), assumed
HFD q0(k,, ky). If there were no heat sources, form of the temperature would be given by: T(k,
T(j$, z) =
q,(k). mslnh(
T(k,
-smh(cu)
z) =
et
Ikjz
lk Id
q,(k).
exp(ar-
IklK
q(k,
z) = q,,(k)
q(k,
z) = -q,(k)
z) = hqo(x)
If the heat between
and
S(k,r, k,, z) is the Fourier transform of the heat source density at depth z. In geophysical applications, the heat sources are not known, and the only constraints on the ture
(Mareschal
lklz) Iklz>a _ Iklz
dk, dk,
by (Carslaw
a2
K
and the heat flow are
expressions
cosh( lk I z) sinh(a)
exp(a-
IkIt) (klz>a
T-k:-k; aZ where
on a
CQJ-cc
xexp[i(k,x+k,Y)]
f(X?
are concentrated
plane layer, the temperature
1972):
distributed
and the layer z = a/ I k (
the surface
tempera-
to be zero, the Fourier
distribution
temperature T(k,
z)=
sources
the surface spectrum
are uniformly is obtained
distributed
z = cu/ I % 1, the
and the plane
as:
l~~~k’~~~~l[l-exp(-lklz) ex (Y -exp(
-a)
sinh( 1X I z)]
Iklz
and trans-
at depth
z
xexp(-lklz)[cosh(cw)-l] Ik)z>a
sinh{ lklz}
In general, this expression transform because the Fourier Bodvarsson (1973) converge.
is not a Fourier integral does not proposed a long
wavelength approximation to continue downward potential fields to arbitrary depth; only the wavenumbers smaller than l/z are retained in the spectrum; larger wave numbers are considered to be part of the noise and are filtered out. Mareschal et al. (1985) considered short wavelengths to be related to the shallow heat sources and included them in the downward continued temperature and heat flow spectra. They examined two heat source distributions: (1) The heat sources are concentrated on the layer z=a/Ikl.
and the heat flow spectrum
-exp(-cr)
is given by:
cosh( lklz)]
Ik(z
4%
z>=4ow ex;;$: Xexp(-
1
(1 - casha)
lklz)
Iklz>a For the two distributions considered, the heat sources vary horizontally like an harmonic function of given wavenumber and are positive as well as negative. The undesirable negative values can be eliminated by adding a constant to the harmonic source distribution so that the heat sources are
J.-C. MARESCHAL
352
positive
everywhere.
must be removed ponent
This
constant
contribution
from the zero wavenumber
quencies
that are not resolved;
Fourier
com-
spectrum
Figure Thermal
that has been determined
used to interpolate
of the heat flow spectrum.
tinued
regime of Eastern Canada
i.e. the part of the
between
3 shows the temperature
to a depth
on a map of Eastern include ported
Canada
all the HFD between
values
44” N and
60 o W and 80 ’ W (Jessop Taylor,
1987; Drury
in Fig. 1. The data that
have
been
50” N and
et al., 1984; Drury
et al., 1987, Mareschal
and
the HFD
data
are irregularly
uted, the usual FFT technique cannot to determine the spectrum. Interpolating on a regular
grid would
smooth
temperature. beneath
be applied the HFD
out the data and
Province.
of November
trum
and the “warmer” cides geographically
they can be resolved
from closely
burg, 1976). This inversion is an undetermined problem as the number of frequencies in the spectrum is much larger than the number
of data. The
the
also be noted
that
crust
implies
6.2 Saguenay
25 1988 (North
earth-
et al., 1989).
The Grenville front does not appear to coincide with any boundary between different thermal provinces.
although
is low
Shield, including
in the lower
for the magnitude
alter the spectrum, and thus effectively eliminate the short wavelength components from the specspaced data points. The Fourier spectrum was thus determined by direct inversion (e.g., Olden-
It should
of
rather than ductile behavior. This is conwith the 29 km focal depth that has been
determined quake
estimate
It shows that the temperature
the low temperature brittle sistent
of the main
a precise
the entire Canadians
Grenville
et al.,
distrib-
and does not provide
con-
conduc-
to be 2.4 W m-’
Such a map is only indicative
trends
re-
between
1989b; Pinet et al., 1991). Figure 2 shows a contoured heat flow map of Eastern Canada. Because
K-‘.
data used in the study are displayed
downward
of 20 km. The thermal
tivity of the crust was assumed The HFD
can be
the data.
The
southeast;
temperature
the boundary
increases between
Appalachian with the
to increase
Figure 4 shows the temperature to 20 km when
the heat
the shield
Province coinSaint-Lawrence
River. The temperature continues ward the Atlantic margin. tinued
toward
the “cold”
downward sources
tocon-
are de-
frequencies that are retained are those that are well resolved by the data. The implicit assumption
termined from surface heat production measurements. It shows the same trends as in the previous
is that the Fourier
map,
spectrum
vanishes
for the fre-
but
with
higher
temperatures.
This
is be-
60” W_
SUPERIOR
Fig. 1. Map of the study area. Dots indicate
the location
of HFD measurements
for Holocene
climatic
sites. The values posted
variations.
are HFD (mW/m’)
adjusted
DOWNWARD
CONTINUATION
OF HEAT
FLOW
Fig, 2. Contoured
often
the basement
5 shows the HFD
REGIME,
EAST
the
measurements,
outcroping metavolcanic rocks and not on basement
underestimate
tion. Figure
THERMAL
353
CANADA
heat flow map of the study area. Contour
cause most of the heat production performed on metasedimentary
AND
heat
downward
or rocks, produc-
continued
lines are 5 mW mm2 apart.
Grenville
metamorphic
Province events
was
between
affected
by several
late Archean
(2650
Ma) and Grenvillian (1000 Ma) time (e.g., Doig, 1977). In the parautochtonous belt south of Grenville front, the high-grade rocks exposed have Archean
metamorphic
ages; paleopressures
in the
to a depth of 20 km. This operation has removed the effect of the shallow sources from the HFD. The trend is similar to that exhibited by the tem-
range 600-800 MPa have been determined (Indares and Martignole, 1989). In this part of the Grenville Province, the shallow crust consists of
perature
Archean
entire
field. The heat flow density shield is low. Apparently,
beneath
the
there is no ther-
rocks that formed
at lower crustal
depth.
The low heat flow is thus the result of depletion
of
mal boundary between the Superior and the Grenville provinces. This absence of contrast in HFD
radiogenic elements of these rocks of lower crustal origin. One could also conjecture that, if indeed an
has several implications.
It is now established
Archean
Fig. 3. Subsurface
map at 20 km depth.
was assumed
temperature
to be 2.4 W m-l
K-l.
that
The contour
“ tectonosphere”
lines are 50 o C apart.
The thermal
The heat sources were assumed to vary as a harmonic plane z = 0.2/k, where k is the wave number.
function
formed
conductivity
under
the cra-
of the upper crust
and to be concentrated
on the
J.-C. MARESCHAL
354
Fig. 4. Subsurface was assumed
temperature
map at 20 km depth.
to be 2.4 W mm’ K-‘.
The contour
The heat sources
uniformly
ton,
it extended
far into
the Grenville
extended
Prosug-
as far as the
Conclusions Because of the limited HFD data available in Eastern Canada, the tectonic immplications of the thermal regime of the Canadian Shield have not yet been
fully explored.
Downward
The thermal
from available
conductivity
heat production
of the upper
measurements
crust
and extend
to 10 km.
is one technique
Province,
beyond the present boundary of the Superior vince (i.e. the Grenville front). This analysis gests that it could have Saint-Lawrence River.
lines are 50 o C apart.
were determined
information
that
may help
from the HFD
The major difficulty
to derive
useful
data.
in such studies is to extract
this information from unevenly distributed data. In this study, the data were inverted to determine their Fourier spectrum. This technique effectively selects the wavelengths of the Fourier spectrum that the data satisfactorily resolve and disregards all other wavelengths. Implicitly, it assumes that the HFD spectrum can be extrapolated where no data are available. The analysis
continuation
of the thermal
to regions
regime of the crust
60%‘_
Fig. 5. Heat flow at a depth harmonic
of 20 km after removal function
of shallow
and to be concentrated
sources
contribution.
on the plane z = 0.2/k,
The heat sources
were assumed
where k is the wave number.
to vary as a
DOWNWARD
CONTINUATION
in eastern
Canada
the Provinces Archean
OF HEAT
shows
ent boundary cluded Grenville
extended
part
contains
the pres-
Province
M.J. and Taylor,
Can. J. Earth Drury,
in-
nature
Also,
the
133: l-14. Huestis,
in radio-
and temperature partly
values in the
the result
but they are mostly
are probably
related
of localized
of deeper
to higher
flow and transient effects opening of the Atlantic.
Appalachian
S.P., 1979. Extremal
reduced
associated
heat
with
Huestis,
The author
gratefully Sciences
S.P.,
the
Huestis,
acknowledges
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