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Interactive property of large thrust sheets with footwall rocks—the Sub thrust interactive duplex hypothesis: A mechanism of dome formation in thrust sheets
231
Teczo~oph.~s~~s, 191 (1991) 237-242 Elsevier
Science Publishers
B.V., Amsterdam
Interactive property of large thrust sheets with footwall rocks- the Subthrust Interactive Duplex Hypothesis: a mechanism of dome formation in thrust sheets Robert D. Hatcher, Jr. Departmeni
of Geological Sciences, University of Tennessee, Knoxville, TN 379961410, and Environmental Oak Ridge National Laboratory, P.O. Box X, Oak Ridge, TN 37831, USA * (Received
August
25,1988;
accepted
August
Sciences Division,
30,1988)
ABSTRACT Hatcher, Jr.. R.D., 1991. Interactive property of large thrust sheets with foot wall rocks- the subthrust interactive duplex hypothesis: a mechanism of dome formation in thrust sheets. In: A. Phrez-Estarin and M.P. Coward (Editors), Deformation and Plate Tectonics. Tectonophysics, 191: 237-242. Recently acquired Appalachian Uttradeep Core Hole (ADCOH) Project site investigation seismic reflection data and geolo$ic data from the Appalachians and several other erogenic belts suggest an important mutually interdependent relationship exists between emplacement of large crystalline thrust sheets and the deforming foreland rocks beneath. This relations~p suggests isolated domes beneath crystalline thrust sheets may be produced by passive folding of the sheet as a result of formation of an antiformal stack duplex in the platform sedimentary sequence beneath. Suggestions that domes in crystalline thrust sheets formed by interference of late open folds is doubtlessly still valid in places, but the platform duplex mechanism is probably also valid to explain the late doming of many crystalline and other large thrust sheets. The dome beneath the Shooting Creek and Brasstown Bald windows in the ADCOH site region is imaged as an antifonnal stack duplex at depth. The Tallulah Falls dome, Grandfather Mountain and Mountain City windows, and Smokies Foothills duplex in the site region and elsewhere in the southern Blue Ridge are all late isolated domes and all are probably or demonstrably underlain by antiformal stack duplexes beneath the Blue edge-~edmont composite crystalline thrust sheet. The Assynt window and footwall duplex benath the Arnabol and Moine thrusts in Scotland, and the Engadine window in the Alps may be similar structures.
data were collected from within the Blue RidgePiedmont composite crystalline thrust sheet in an area where several isolated domes occur. Interpretation of arching reflector packages in presumed foreland sedimentary rocks beneath the crystalline
Intmductioe The purpose of this paper is to outline a hypothesis related to the process of duplex formation in overthrust terranes and ultimately to plate collision processes. This hypothesis, called the Subth~t mulated
~ntera~t~~~ Dupfex Hypothesis, was forduring analysis of seismic reflection data
from the Appalachian Ultradeep COH) Project site investigation Appalachians
* Operated
sheet revealed that these arching reflector packages may be duplexes. Their locations are precisely
(Coruh
by Martin
U.S. Department
beneath
et al., 1987). All of these
Marietta
of Energy
Energy
Systems,
under contract
Inc., for the
No. DE-AC05-84
0 1991 - Elsevier Science Publishers
domes.
above duplexes, but assumed the processes of thrusting, metamo~~sm and cleavage formation in the internal parts of an orogen are coeval and interrelated. Detailed studies of timing of fabric development and metamorphism in most orogens have shown that assumption to be incorrect. A
oR21400.
0040-1951/91/$03.50
some of the isolated
Boyer and Elliott (1981) discussed the formation of folds and culminations in the roof thrusts
Core Hole (ADin the southern
B.V.
R.D. HATCHER
238
basic assumption by abundant is emplaced structures
of the present
paper,
data, is that the dominant cold and transports formed
during
and
events
related
here also apply Boyer
and
nature
to roof
thrusts
in foreland
belts where the original Elliott
(1981)
related
to the
sheets
crystalline
of crystalline
earlier
events
simpler
and
thrust
rocks
may contain
sheets
consist
sheets
of several
sheets, ophiolites,
of western
the Blue Ridge-Piedmont and central Appalachians
Canada
collision. dominantly
a more internal
zone of transpression,
nant
strike-slip
(Eisbacher,
BLUE
1985;
and
spatial
in overthrust
ter-
occur
4: 1 and 1 : 1; they com-
on the hinterland belts.
Boyer
sides of foreland and
Elliott
(1981)
reflection
data
acquired
Appalachian
Ultradeep
investigation
has revealed
as part
of the
Core Hole (ADCOH) the presence
site
of antifor-
ma1 stack duplexes probably composed of Paleozoic platform margin rocks beneath isolated domes in
the
Blue
Ridge-Piedmont
crystalline
thrust
that crystalline
sheets,
sheet (Fig. 1). It was recently
then domi-
because
and
RIDGE
proposed
they are some of the largest
CHAUGA 1BELT j
6 10 _ Horizontal and Vertical 20
strength,
form where the ratios of weak to
units are between
Seismic
into
Hatcher
and
(1985) recog-
Boyer and Elliott (1981) and Mitra (1986) called antiformal-stack and foreland-dipping duplexes.
and
partitioned
1970;
of roof thrusts occurs as a result of duplex formation, and particularly the formation of the types
These structures commonly dip-slip continent-directed
that is frequently
is the
1986; Mitra
and Hatcher
formation
strong
thrust
terranes
(Dahlstrom,
Mitra,
are scale,
continental
Elliott and Johnson (1980) and Diegel (1986) and others have constructed sections that show arching
sheet of the and the Moine
sense of motion
there
monly
fold and
sheet in Scotland. All, except the Yukon-Tanana sheet may be directly attributable to continentcontinent have a
1981;
of duplex
ranes. Duplexes
blocks. Examples include the Austroalpine sheet in the Eastern Alps, the Yukon-Tanana sheet in Alaska, southern
of overthrust
may
early colli-
the
structures
di-
during
Diachroneity and/or
with
property of duplex
that
controls
ural features on the Earth, comparable in size with large accreted terranes and microcontinental
Cordillera
promontories
of
nized
of
by a series of
and tectonic slides, that are moved together in the later-formed composite sheet (Hatcher and Williams, 1986). These are some of the largest struct-
the northern
sion
event.
dip-
be slightly
are produced
collision
Boyer, 1986). Costello
formed
types, e.g., thin-skinned
to oblique
Boyer and Elliott,
coeval
of events is best applied.
Composite
collision
be related
formation
of
may
but all elements
margin(s). Another
fold
assumption
of the respective
components
the same major
to
peak. This is clearly the
case for the Blue Ridge-Piedmont, Moine, Jotun, and Austroalpine sheets. The principles outlined and thrust
1987). The timing
strike-slip
achronous,
earlier penetrative
earlier
the rnet~o~~c-the~al
Edelman,
supported roof thrust
Jr.
tectonic
fea-
INNER PIEDMONT
Kilometers
Fig. 1. Cross section through part of the Blue Ridge, Brevard fault wne and western Piedmont of the Carolinas and Georgia southern Appalachians
based upon ADCOH
Project site investigation
seismic reflection and surface geologic data. The large duplex at the
west end of the section is shown in greater detail in Fig. 3.
INTERACTIVE
PROPERTY
tures in mountain fluid
as they
margin
tion pathway.
FOOTWALL
onto
239
ROCKS
of
thought
to be the result
collision
a continental
(see
Hatcher
references
therein).
and foreland
and hydrocarbons structures
migration
if the crystalline
low temperature
recently
in the migra-
The antiformal-stack barriers
that may
duplexes
beneath
may
crystalline
unconventional
source
for the notion belt deformation
by the crystalline
sheet was emplaced
at a
Recently the internal
( < 300 o C). The antiformal-stack
consequently
except thrust
par-
1986,
sheets
process
for
was thought
mechanically that
and until
independent,
the foreland
was driven
fold and
ahead
of and
sheet.
acquired seismic reflection data from parts of the southern Appalachian
may prove
to be a future
Blue Ridge-Piedmont
of methane
and other
(Coruh
hy-
Williams,
The emplacement
to be largely
of hydr~arbons,
of continent-continent
and
crystalline
suitable
duplexes
WITH
1986). These fluids may carry with
sheets to impede ticularly
SHEETS
expel1 huge volumes
emplaced
in appropriate
constitute
THRUST
metals
(Oliver,
be trapped
chains,
are
them dissolved
OF LARGE
composite
et al., 1987) indicate
crystalline
sheet
a significant
amount
drocarbons.
of interaction between the crystalline sheet and the foreland beneath, with each affecting the other
Interactive property of large thrust sheets
during
Large onto
thrust
a continental
earlier period of a passive
sheets
are
platform
commonly that
emplaced
experienced
an
of rifting followed by development margin stratigraphy (Fig. 2). This
emplacement
of the crystalline
formation
of both
the crystalline
foreland
has occurred
(Fig.
assemblage
of the crystalline
sheet
to
move.
resulted
the
duplexin doming
as the crystalline Seismic
De-
and
1). Extensive
ing of the platform continued
sheet.
sheet
sheet
reflection
data
stratigraphy contains weak units into which the master detachment propagated as it ramped from the ductile-brittle transition into the platform rift and passive margin stratigraphic assemblage. Foreland thrusts are driven ahead of the advanc-
acquired during the Appalachian Ultradeep Core Hole (ADCOH) Project site investigation (Coruh et al, 1987) provide greater resolution than any collected previously in a crystalline terrane. In particular, these data provide the strongest evi-
ing crystalline sheet(s), except those forming outof-sequence. The crystalline sheet utilizes the same weak units as the foreland sheet as it moves over
dence without drilling that platform sedimentary rocks were deformed into antiformal stack duplexes during emplacement of the crystalline
the platform of both ferences strength. crystalline
assemblage,
and the overall
types becomes similar, with related mostly to relative The emplacement of large thrust sheets has for some
TRAJECTORY
behavior major size
sheet, and in turn
difand
into broad ADCOH
composite time been
deformed
the crystalline
domes (Fig. 3). Consequently, site
combination
study with
seismic
surface
reflection
geologic
sheet the new
data,
data,
in
suggest
that @‘reevolution of stnrctures during emplacement
OF FUTURE
FRAGMENT Fig. ‘2. Development continent-continent the rifted margin
of a passsive collision,
margin
stratigraphy
the master detachment
elastic sediments
on continental
propagates
crust
following
from the ductile-brittle
and then into the weak unit(s) within sequence.
a period
of rifting
transition
as a crystalline
the basal elastic-carbonate
and extention.
assemblage
thrust, within
During
ramps
into
the patfrom
R.D. HATCHER
Jr.
240 IN SECTION
1350
1400
1
4
VL9 P
Hayesvile
HAYESVILLE THRUST t7Gu I
1800
HAYEWLLE
lSzrI=T
Fold cHJNKY GAL
MOUNTAIN FAUT,
in Section i
1400 15501:
1Sm
1350
KM
KM
‘\I
I I
II
C”h,Pl
B-
lhlC
CRYSTALLINE
8
p8 BASEMENT GRABEN
(7)
Fig. 3. Part of the west end of ADCOH seismic reflection line 3 (top) beneath the Shooting Creek and Brasstown Bald windows along the North Carolina-Georgia the reflectors
border in the southern Appalachian Blue Ridge (Coruh et al., 1987). The middle frame is a tracing of
in the seismic section and the bottom frame is an interpretation of the data. If the interpretation crystalline sheet was arched by construction of the duplex in the platform rocks.
is correct,
the
INTERACTIVE
PROPERTV
OF LARGE
Crystalline
THRUST
SHEETS
WITH
FOOTWALL
the
Sheet
241
ROCKS
external
worldwide
L
Platform -Autochthonous
Crystalline
amples
include
Moine
thrust
Elliott
Basement
Sheet
----_
window
Cove/
Tuckaleechee
(Diegel,
et al.,
the 1923;
City/Limestone and
Cove/Wear
the
Cove
in the
Cades
windows
southern
window
in the eastern
example. Duplexing beneath crystalline
beneath et al.,
and Reed, 1970; Boyer 1986),
1986b)
Ex-
the ~r~dfather
Mountain
The Engadine
retta nappe
window (Peach
(Bryant
sheets
by duplexes.
1980) and
19X1),
windows
crystalline
cored
Scotland
Cove
lachians.
large
the Assynt in
Elliott,
(Hatcher
Basement
of
and Johnson,
Mountain and Doming of Crystalline
fringes
are commonly
through
Appathe Silv-
Alps may be a further
of foreland sedimentary rocks sheets has been described by
Hossack (1983) and observed by Hatcher (unpublished) in Sweden and Norway. The interactive property
is implicit
in sections
through
many
of
these structures (see figs. 1X and 24 in Elliott and Johnson, 1980, and fig. 29 in Boyer and Elliott, 1981). The interactive doming property appears to be most commonly associated with the emplacement Snakehead in Platform Fig. 4. Subthrust interaction
Duplex Rocks
Interactive
of a crystalline
ing the development
Basement Duplex
thrust
of large crystalline
Hypothesis.
Progressive
sheet with its platform
of first a thrust in the platform
show-
(top), then
a duplex that arches the crystalline
sheet (middle)
which evolves
into an antiformal
that enhances
the arching
stack (bottom) the crystalline
of
sheet.
of a crystalline thrust sheet onto a continental platform is a rn~t~a~~y ~ntera~~~ve process between the sheet and the platform beneath (Hatcher et al., 1986a), a statement of the Subthrust Interactive Duplex
Hypothesis.
Antiformal
stack
duplexes
sheets. There is no obvious this process should not thrust sheets, particularly considered,
been interpreted
the crystalline
of additional
late domes
earlier structures transported sheet (Fig. 4). Isolated domes
deforming
by the composite in crystalline thrust
to indicate
occur beneath where relative
is commonly
not
that
smaller size is
observed.
The
Numerous isolated domes that have not been breached by erosion to expose the basal detachment and the foreland rocks beneath occur in crystalline thrust sheets. These have traditionally and-basin,
into
but
reason
thrust
interactive process may be triggered by threshold values of thickness of dominant unit(s), area, trapped fluid, or other critical parameters.
form in the platform in response to emplacement of the crystalline thrust sheet which in turn arch sheet
sheets and large foreland
to be the result of Type 1, dome-
fold interference nearby
domes
(Ramsay, and basins
1967). Lack belonging
to the same set has always left some doubt whether this is the correct interpretation,
as to or if
sheeets previously throught to be formed by fold interference should be reexamined with this hy-
some other mechanism is responsible for the formation of these structures. That they are isolated
pothesis in mind. Extensive duplexing beneath the unbreached Tallulah Falls dome and Shooting Creek/Brasstown Bald windows imaged in the Applalachian Ultradeep Core Hole (ADCOH) Project site investigation seismic reflection data (Fig. 3) provide stong evidence that this is a viable mechanism. Erosionally breached antiforms along
both in space and time should indicate another mechanism may be responsible for their formation. The subthrust interactive duplex hypothesis provides an explanation for formation of these structures. The fact that these structures are also potential hydrocarbon traps provides the basis for more than purely scientific interest.
R.D. HATCHER
242
Conclusions
Dahlstrom,
C.D.A.,
margin
(1) Doming sheets
occurs
of crystalline
as the sheet interacts
forms its footwall mation
rocks during
of antiformal
rocks beneath and
stack
isolated
interactive
(2) Isolated duplexing
emplacement.
duplexes
domes. duplex
domes
of platform
a large thrust migration (primarily
with and deFor-
in footwall
large thrust sheets deforms
produces
subthrust
and other large thrust
This
the sheet
is called
the
hypothesis.
formed
sheet may provide
interactive
rocks beneath barriers
to fluid
and serve as untapped hydrocarbon gas) reservoirs where excessive tempera-
tures have not been reached
in the platform
rocks.
F., 1986. Topological
networks,
examples
nessee. J. Struct. Eisbacher, and
I am grateful to the organizers of the conference on Deformation and Plate Tectonics for inviting me to present this paper in Oviedo, Spain, to S.H.
Edelman
for
presenting it for me because of a schedule conflict. Support by the U.S. National Science Foundation Grant EAR-8417894 is gratefully acknowledged. Reviews by R.A. viewer significantly 1 am responsible tation.
Price and an anonymous improved the manuscript;
rebut
for all errors of fact or interpre-
Elliott,
Trans. Hatcher,
systems.
Am. Assoc.
Pet. Geol. Bull., 66: 1196-1230. father
Mountain
Tennessee. Coruh,
window
U.S. Geol. Surv., Profess.
C., Costain,
J.K.,
Hatcher,
liams, R.T. and Phinney, vibroseis study. Costello,
profiling:
J. R. Astron. Hatcher,
17: 554.
Carolina
and
Pap., 615: 190 p.
ultradeep
T.L., Wil-
from regional core
and strike-slip
Geol.
Econ.
faults
and
Deformation,
Paleontol.
hole
site
and Sot.
Appa-
the boundary Am., Abstr.
1980. Structural
Mineral.,
sheets
and
Sci., 71: 69-96. Appalachians:
of Alleghanian
sheets.
parti-
thrusting
collision.
Geol.
R.T., 1986. Mechanical
Part
their
of erogenic
in
19: 89.
R.D., Jr. and Williams,
behavior
evolution
belt, NW Scotland.
S.H., 1987. Macro-scale
and central
Progr.,
thrust
thrust
Earth
as products
Sot. Am., Abstr.
I: Taxonomy
relationships
model
of crystalline
to the
mechanical
belts. Geol. Sot. Am. Bull., 97: 975-
985. Hatcher,
R.D.,
Jr., Williams,
J.K., 1986a, ADCOH new subthrust mation
duplex
thrust
Jr., Costello,
The Smokies
Foothills
the Guess Creek fault: and Neuman.
sheets.
Geol.
J.O. and
duplex
for-
a corollary
constructed
S.E., 1986b. significance
to the mapping Progr.,
through
of
of King
18: 226.
the Scandinavian
with the aid of branch-line
maps.
Geol., 5: 1033111. of duplexes.
geometry.
Fluids
balance
J. Struct.
structures
structural
Am. Assoc.
J., 1986.
and
8: 291-304.
imbricate
position
and
thrust
sys-
hydrocarbon
Pet. Geol. Bull., 70: 1087-1112. tectonically
their role in hydrocarbon
migration
C.H.,
and deforma-
Geol..
expelled
B.N., Home,
haus,
for a
for dome
Edelman,
Geol. Sot. of Am., Abstr.
S., 1986. Duplex
belts:
Costain,
evidence
Sot. Am., Abstr.
and possible
G. and Boyer, S.E. 1986. Energy
Oliver,
C. and
data:
mechanism
J.R., 1983. A cross-section
tems:
Peach,
Coruh,
18: 631. R.D.,
Hossack,
R.T.,
seismic reflection
platform
in crystalline
Progr., Hatcher,
Geology,
erogenic geo-
14: 99-102.
J., Clough,
1923. Assynt
from
and other
CT.,
District.
Cadell,
H.M.
and Din-
Geol.
Surv. Great
Bri-
Fracturing
of Rocks.
Mc-
tain, scale l/63,360. Ramsay,
Jr., 1985, Southern
transition
nucleation.
Ten-
In: K.T. Biddle
Strike-slip
Sot.
M.R.W.,
in the southern
logic phenomena.
Sot., 89: 147-156.
R.D.,
foreland-hinterland for duplex
North
R.D., Jr., Pratt,
Appalachian
Geophys.
lachian
of the Grand-
R.A., 1987. Results
J.O. and
conditions Progr.,
and vicinity,
strike-slip
(Editors),
R. Sot. Edinburgh,
potential.
Reed, J.C., Jr., 1970. Geology
thrust
City window,
Cordillera.
R.D., Jr. and Edelman,
tioning
Mitra,
B. and
Pericollisional
part of the Moine
tion mechanisms D., 1981. Thrust
on imbricate
8: 269-279.
Canadian
D. and Johnson,
the northern
Mitra,
References
Bryant,
basins,
Caledonides
SE. and Elliott,
Geol.,
N. Christie-Blick
J. Struct.
Boyer,
constraints
Basin, and Sedimentation.
thrust
and
in the eastern Can. Pet. Geol.,
from the Mountain
G. H., 1985.
synorogenic
for single
1987,
geology
Mountains.
18: 332-406. Diegel,
Hatcher,
Acknowledgments
in September,
Structural Rocky
Spec Publ., 37: 265-282.
by
sedimentary
1970.
of the Canadian
Jr.
J.G.,
Graw-Hill,
1967. Folding
and
New York, 568 pp.
Teczo~oph.~s~~s, 191 (1991) 237-242 Elsevier
Science Publishers
B.V., Amsterdam
Interactive property of large thrust sheets with footwall rocks- the Subthrust Interactive Duplex Hypothesis: a mechanism of dome formation in thrust sheets Robert D. Hatcher, Jr. Departmeni
of Geological Sciences, University of Tennessee, Knoxville, TN 379961410, and Environmental Oak Ridge National Laboratory, P.O. Box X, Oak Ridge, TN 37831, USA * (Received
August
25,1988;
accepted
August
Sciences Division,
30,1988)
ABSTRACT Hatcher, Jr.. R.D., 1991. Interactive property of large thrust sheets with foot wall rocks- the subthrust interactive duplex hypothesis: a mechanism of dome formation in thrust sheets. In: A. Phrez-Estarin and M.P. Coward (Editors), Deformation and Plate Tectonics. Tectonophysics, 191: 237-242. Recently acquired Appalachian Uttradeep Core Hole (ADCOH) Project site investigation seismic reflection data and geolo$ic data from the Appalachians and several other erogenic belts suggest an important mutually interdependent relationship exists between emplacement of large crystalline thrust sheets and the deforming foreland rocks beneath. This relations~p suggests isolated domes beneath crystalline thrust sheets may be produced by passive folding of the sheet as a result of formation of an antiformal stack duplex in the platform sedimentary sequence beneath. Suggestions that domes in crystalline thrust sheets formed by interference of late open folds is doubtlessly still valid in places, but the platform duplex mechanism is probably also valid to explain the late doming of many crystalline and other large thrust sheets. The dome beneath the Shooting Creek and Brasstown Bald windows in the ADCOH site region is imaged as an antifonnal stack duplex at depth. The Tallulah Falls dome, Grandfather Mountain and Mountain City windows, and Smokies Foothills duplex in the site region and elsewhere in the southern Blue Ridge are all late isolated domes and all are probably or demonstrably underlain by antiformal stack duplexes beneath the Blue edge-~edmont composite crystalline thrust sheet. The Assynt window and footwall duplex benath the Arnabol and Moine thrusts in Scotland, and the Engadine window in the Alps may be similar structures.
data were collected from within the Blue RidgePiedmont composite crystalline thrust sheet in an area where several isolated domes occur. Interpretation of arching reflector packages in presumed foreland sedimentary rocks beneath the crystalline
Intmductioe The purpose of this paper is to outline a hypothesis related to the process of duplex formation in overthrust terranes and ultimately to plate collision processes. This hypothesis, called the Subth~t mulated
~ntera~t~~~ Dupfex Hypothesis, was forduring analysis of seismic reflection data
from the Appalachian Ultradeep COH) Project site investigation Appalachians
* Operated
sheet revealed that these arching reflector packages may be duplexes. Their locations are precisely
(Coruh
by Martin
U.S. Department
beneath
et al., 1987). All of these
Marietta
of Energy
Energy
Systems,
under contract
Inc., for the
No. DE-AC05-84
0 1991 - Elsevier Science Publishers
domes.
above duplexes, but assumed the processes of thrusting, metamo~~sm and cleavage formation in the internal parts of an orogen are coeval and interrelated. Detailed studies of timing of fabric development and metamorphism in most orogens have shown that assumption to be incorrect. A
oR21400.
0040-1951/91/$03.50
some of the isolated
Boyer and Elliott (1981) discussed the formation of folds and culminations in the roof thrusts
Core Hole (ADin the southern
B.V.
R.D. HATCHER
238
basic assumption by abundant is emplaced structures
of the present
paper,
data, is that the dominant cold and transports formed
during
and
events
related
here also apply Boyer
and
nature
to roof
thrusts
in foreland
belts where the original Elliott
(1981)
related
to the
sheets
crystalline
of crystalline
earlier
events
simpler
and
thrust
rocks
may contain
sheets
consist
sheets
of several
sheets, ophiolites,
of western
the Blue Ridge-Piedmont and central Appalachians
Canada
collision. dominantly
a more internal
zone of transpression,
nant
strike-slip
(Eisbacher,
BLUE
1985;
and
spatial
in overthrust
ter-
occur
4: 1 and 1 : 1; they com-
on the hinterland belts.
Boyer
sides of foreland and
Elliott
(1981)
reflection
data
acquired
Appalachian
Ultradeep
investigation
has revealed
as part
of the
Core Hole (ADCOH) the presence
site
of antifor-
ma1 stack duplexes probably composed of Paleozoic platform margin rocks beneath isolated domes in
the
Blue
Ridge-Piedmont
crystalline
thrust
that crystalline
sheets,
sheet (Fig. 1). It was recently
then domi-
because
and
RIDGE
proposed
they are some of the largest
CHAUGA 1BELT j
6 10 _ Horizontal and Vertical 20
strength,
form where the ratios of weak to
units are between
Seismic
into
Hatcher
and
(1985) recog-
Boyer and Elliott (1981) and Mitra (1986) called antiformal-stack and foreland-dipping duplexes.
and
partitioned
1970;
of roof thrusts occurs as a result of duplex formation, and particularly the formation of the types
These structures commonly dip-slip continent-directed
that is frequently
is the
1986; Mitra
and Hatcher
formation
strong
thrust
terranes
(Dahlstrom,
Mitra,
are scale,
continental
Elliott and Johnson (1980) and Diegel (1986) and others have constructed sections that show arching
sheet of the and the Moine
sense of motion
there
monly
fold and
sheet in Scotland. All, except the Yukon-Tanana sheet may be directly attributable to continentcontinent have a
1981;
of duplex
ranes. Duplexes
blocks. Examples include the Austroalpine sheet in the Eastern Alps, the Yukon-Tanana sheet in Alaska, southern
of overthrust
may
early colli-
the
structures
di-
during
Diachroneity and/or
with
property of duplex
that
controls
ural features on the Earth, comparable in size with large accreted terranes and microcontinental
Cordillera
promontories
of
nized
of
by a series of
and tectonic slides, that are moved together in the later-formed composite sheet (Hatcher and Williams, 1986). These are some of the largest struct-
the northern
sion
event.
dip-
be slightly
are produced
collision
Boyer, 1986). Costello
formed
types, e.g., thin-skinned
to oblique
Boyer and Elliott,
coeval
of events is best applied.
Composite
collision
be related
formation
of
may
but all elements
margin(s). Another
fold
assumption
of the respective
components
the same major
to
peak. This is clearly the
case for the Blue Ridge-Piedmont, Moine, Jotun, and Austroalpine sheets. The principles outlined and thrust
1987). The timing
strike-slip
achronous,
earlier penetrative
earlier
the rnet~o~~c-the~al
Edelman,
supported roof thrust
Jr.
tectonic
fea-
INNER PIEDMONT
Kilometers
Fig. 1. Cross section through part of the Blue Ridge, Brevard fault wne and western Piedmont of the Carolinas and Georgia southern Appalachians
based upon ADCOH
Project site investigation
seismic reflection and surface geologic data. The large duplex at the
west end of the section is shown in greater detail in Fig. 3.
INTERACTIVE
PROPERTY
tures in mountain fluid
as they
margin
tion pathway.
FOOTWALL
onto
239
ROCKS
of
thought
to be the result
collision
a continental
(see
Hatcher
references
therein).
and foreland
and hydrocarbons structures
migration
if the crystalline
low temperature
recently
in the migra-
The antiformal-stack barriers
that may
duplexes
beneath
may
crystalline
unconventional
source
for the notion belt deformation
by the crystalline
sheet was emplaced
at a
Recently the internal
( < 300 o C). The antiformal-stack
consequently
except thrust
par-
1986,
sheets
process
for
was thought
mechanically that
and until
independent,
the foreland
was driven
fold and
ahead
of and
sheet.
acquired seismic reflection data from parts of the southern Appalachian
may prove
to be a future
Blue Ridge-Piedmont
of methane
and other
(Coruh
hy-
Williams,
The emplacement
to be largely
of hydr~arbons,
of continent-continent
and
crystalline
suitable
duplexes
WITH
1986). These fluids may carry with
sheets to impede ticularly
SHEETS
expel1 huge volumes
emplaced
in appropriate
constitute
THRUST
metals
(Oliver,
be trapped
chains,
are
them dissolved
OF LARGE
composite
et al., 1987) indicate
crystalline
sheet
a significant
amount
drocarbons.
of interaction between the crystalline sheet and the foreland beneath, with each affecting the other
Interactive property of large thrust sheets
during
Large onto
thrust
a continental
earlier period of a passive
sheets
are
platform
commonly that
emplaced
experienced
an
of rifting followed by development margin stratigraphy (Fig. 2). This
emplacement
of the crystalline
formation
of both
the crystalline
foreland
has occurred
(Fig.
assemblage
of the crystalline
sheet
to
move.
resulted
the
duplexin doming
as the crystalline Seismic
De-
and
1). Extensive
ing of the platform continued
sheet.
sheet
sheet
reflection
data
stratigraphy contains weak units into which the master detachment propagated as it ramped from the ductile-brittle transition into the platform rift and passive margin stratigraphic assemblage. Foreland thrusts are driven ahead of the advanc-
acquired during the Appalachian Ultradeep Core Hole (ADCOH) Project site investigation (Coruh et al, 1987) provide greater resolution than any collected previously in a crystalline terrane. In particular, these data provide the strongest evi-
ing crystalline sheet(s), except those forming outof-sequence. The crystalline sheet utilizes the same weak units as the foreland sheet as it moves over
dence without drilling that platform sedimentary rocks were deformed into antiformal stack duplexes during emplacement of the crystalline
the platform of both ferences strength. crystalline
assemblage,
and the overall
types becomes similar, with related mostly to relative The emplacement of large thrust sheets has for some
TRAJECTORY
behavior major size
sheet, and in turn
difand
into broad ADCOH
composite time been
deformed
the crystalline
domes (Fig. 3). Consequently, site
combination
study with
seismic
surface
reflection
geologic
sheet the new
data,
data,
in
suggest
that @‘reevolution of stnrctures during emplacement
OF FUTURE
FRAGMENT Fig. ‘2. Development continent-continent the rifted margin
of a passsive collision,
margin
stratigraphy
the master detachment
elastic sediments
on continental
propagates
crust
following
from the ductile-brittle
and then into the weak unit(s) within sequence.
a period
of rifting
transition
as a crystalline
the basal elastic-carbonate
and extention.
assemblage
thrust, within
During
ramps
into
the patfrom
R.D. HATCHER
Jr.
240 IN SECTION
1350
1400
1
4
VL9 P
Hayesvile
HAYESVILLE THRUST t7Gu I
1800
HAYEWLLE
lSzrI=T
Fold cHJNKY GAL
MOUNTAIN FAUT,
in Section i
1400 15501:
1Sm
1350
KM
KM
‘\I
I I
II
C”h,Pl
B-
lhlC
CRYSTALLINE
8
p8 BASEMENT GRABEN
(7)
Fig. 3. Part of the west end of ADCOH seismic reflection line 3 (top) beneath the Shooting Creek and Brasstown Bald windows along the North Carolina-Georgia the reflectors
border in the southern Appalachian Blue Ridge (Coruh et al., 1987). The middle frame is a tracing of
in the seismic section and the bottom frame is an interpretation of the data. If the interpretation crystalline sheet was arched by construction of the duplex in the platform rocks.
is correct,
the
INTERACTIVE
PROPERTV
OF LARGE
Crystalline
THRUST
SHEETS
WITH
FOOTWALL
the
Sheet
241
ROCKS
external
worldwide
L
Platform -Autochthonous
Crystalline
amples
include
Moine
thrust
Elliott
Basement
Sheet
----_
window
Cove/
Tuckaleechee
(Diegel,
et al.,
the 1923;
City/Limestone and
Cove/Wear
the
Cove
in the
Cades
windows
southern
window
in the eastern
example. Duplexing beneath crystalline
beneath et al.,
and Reed, 1970; Boyer 1986),
1986b)
Ex-
the ~r~dfather
Mountain
The Engadine
retta nappe
window (Peach
(Bryant
sheets
by duplexes.
1980) and
19X1),
windows
crystalline
cored
Scotland
Cove
lachians.
large
the Assynt in
Elliott,
(Hatcher
Basement
of
and Johnson,
Mountain and Doming of Crystalline
fringes
are commonly
through
Appathe Silv-
Alps may be a further
of foreland sedimentary rocks sheets has been described by
Hossack (1983) and observed by Hatcher (unpublished) in Sweden and Norway. The interactive property
is implicit
in sections
through
many
of
these structures (see figs. 1X and 24 in Elliott and Johnson, 1980, and fig. 29 in Boyer and Elliott, 1981). The interactive doming property appears to be most commonly associated with the emplacement Snakehead in Platform Fig. 4. Subthrust interaction
Duplex Rocks
Interactive
of a crystalline
ing the development
Basement Duplex
thrust
of large crystalline
Hypothesis.
Progressive
sheet with its platform
of first a thrust in the platform
show-
(top), then
a duplex that arches the crystalline
sheet (middle)
which evolves
into an antiformal
that enhances
the arching
stack (bottom) the crystalline
of
sheet.
of a crystalline thrust sheet onto a continental platform is a rn~t~a~~y ~ntera~~~ve process between the sheet and the platform beneath (Hatcher et al., 1986a), a statement of the Subthrust Interactive Duplex
Hypothesis.
Antiformal
stack
duplexes
sheets. There is no obvious this process should not thrust sheets, particularly considered,
been interpreted
the crystalline
of additional
late domes
earlier structures transported sheet (Fig. 4). Isolated domes
deforming
by the composite in crystalline thrust
to indicate
occur beneath where relative
is commonly
not
that
smaller size is
observed.
The
Numerous isolated domes that have not been breached by erosion to expose the basal detachment and the foreland rocks beneath occur in crystalline thrust sheets. These have traditionally and-basin,
into
but
reason
thrust
interactive process may be triggered by threshold values of thickness of dominant unit(s), area, trapped fluid, or other critical parameters.
form in the platform in response to emplacement of the crystalline thrust sheet which in turn arch sheet
sheets and large foreland
to be the result of Type 1, dome-
fold interference nearby
domes
(Ramsay, and basins
1967). Lack belonging
to the same set has always left some doubt whether this is the correct interpretation,
as to or if
sheeets previously throught to be formed by fold interference should be reexamined with this hy-
some other mechanism is responsible for the formation of these structures. That they are isolated
pothesis in mind. Extensive duplexing beneath the unbreached Tallulah Falls dome and Shooting Creek/Brasstown Bald windows imaged in the Applalachian Ultradeep Core Hole (ADCOH) Project site investigation seismic reflection data (Fig. 3) provide stong evidence that this is a viable mechanism. Erosionally breached antiforms along
both in space and time should indicate another mechanism may be responsible for their formation. The subthrust interactive duplex hypothesis provides an explanation for formation of these structures. The fact that these structures are also potential hydrocarbon traps provides the basis for more than purely scientific interest.
R.D. HATCHER
242
Conclusions
Dahlstrom,
C.D.A.,
margin
(1) Doming sheets
occurs
of crystalline
as the sheet interacts
forms its footwall mation
rocks during
of antiformal
rocks beneath and
stack
isolated
interactive
(2) Isolated duplexing
emplacement.
duplexes
domes. duplex
domes
of platform
a large thrust migration (primarily
with and deFor-
in footwall
large thrust sheets deforms
produces
subthrust
and other large thrust
This
the sheet
is called
the
hypothesis.
formed
sheet may provide
interactive
rocks beneath barriers
to fluid
and serve as untapped hydrocarbon gas) reservoirs where excessive tempera-
tures have not been reached
in the platform
rocks.
F., 1986. Topological
networks,
examples
nessee. J. Struct. Eisbacher, and
I am grateful to the organizers of the conference on Deformation and Plate Tectonics for inviting me to present this paper in Oviedo, Spain, to S.H.
Edelman
for
presenting it for me because of a schedule conflict. Support by the U.S. National Science Foundation Grant EAR-8417894 is gratefully acknowledged. Reviews by R.A. viewer significantly 1 am responsible tation.
Price and an anonymous improved the manuscript;
rebut
for all errors of fact or interpre-
Elliott,
Trans. Hatcher,
systems.
Am. Assoc.
Pet. Geol. Bull., 66: 1196-1230. father
Mountain
Tennessee. Coruh,
window
U.S. Geol. Surv., Profess.
C., Costain,
J.K.,
Hatcher,
liams, R.T. and Phinney, vibroseis study. Costello,
profiling:
J. R. Astron. Hatcher,
17: 554.
Carolina
and
Pap., 615: 190 p.
ultradeep
T.L., Wil-
from regional core
and strike-slip
Geol.
Econ.
faults
and
Deformation,
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hole
site
and Sot.
Appa-
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1980. Structural
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parti-
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their
of erogenic
in
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R.D., Jr. and Williams,
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S.H., 1987. Macro-scale
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thrust
Earth
as products
Sot. Am., Abstr.
I: Taxonomy
relationships
model
of crystalline
to the
mechanical
belts. Geol. Sot. Am. Bull., 97: 975-
985. Hatcher,
R.D.,
Jr., Williams,
J.K., 1986a, ADCOH new subthrust mation
duplex
thrust
Jr., Costello,
The Smokies
Foothills
the Guess Creek fault: and Neuman.
sheets.
Geol.
J.O. and
duplex
for-
a corollary
constructed
S.E., 1986b. significance
to the mapping Progr.,
through
of
of King
18: 226.
the Scandinavian
with the aid of branch-line
maps.
Geol., 5: 1033111. of duplexes.
geometry.
Fluids
balance
J. Struct.
structures
structural
Am. Assoc.
J., 1986.
and
8: 291-304.
imbricate
position
and
thrust
sys-
hydrocarbon
Pet. Geol. Bull., 70: 1087-1112. tectonically
their role in hydrocarbon
migration
C.H.,
and deforma-
Geol..
expelled
B.N., Home,
haus,
for a
for dome
Edelman,
Geol. Sot. of Am., Abstr.
S., 1986. Duplex
belts:
Costain,
evidence
Sot. Am., Abstr.
and possible
G. and Boyer, S.E. 1986. Energy
Oliver,
C. and
data:
mechanism
J.R., 1983. A cross-section
tems:
Peach,
Coruh,
18: 631. R.D.,
Hossack,
R.T.,
seismic reflection
platform
in crystalline
Progr., Hatcher,
Geology,
erogenic geo-
14: 99-102.
J., Clough,
1923. Assynt
from
and other
CT.,
District.
Cadell,
H.M.
and Din-
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Surv. Great
Bri-
Fracturing
of Rocks.
Mc-
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Jr., 1985, Southern
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nucleation.
Ten-
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R.D.,
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North
R.D., Jr., Pratt,
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