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Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
Journal
of
Geodynamics
xxx (2013) xxx–
xxx
Contents
lists
available
at
SciVerse
ScienceDirect
Journal
of
Geodynamics
j
ourna
l
h
om
epage:
/>A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas
Cung
Thuo
.
ng
Chí
a,∗
,
John
W.
Geissman
b,1
a
Institute
of
Geological
Sciences,
Vietnam
Academy
of
Science
&
Technology
84
Chua
Lang
Street,
Dong
Da
Dist.,
Hanoi,
Viet
Nam
b
Department
of
Earth
and
Planetary
Sciences,
MSC
03
2040,
1
University
of
New
Mexico,
Albuquerque,
NM
87131-0001,
United
States
a
r
t
i
c
l
e
i
n
f
o
Article
history:
Received
22
July
2010
Received
in
revised
form
19
November
2011
Accepted
22
November
2011
Available online xxx
Keywords:
Paleomagnetism
Tectonics
Cretaceous
Vietnam
Indochina
South
China
Extrusion
a
b
s
t
r
a
c
t
Available
paleomagnetic
data
from
rock
formations
of
Cretaceous
age
from
Vietnam,
Indochina
and
South
China
are
compiled
and
reviewed
in
the
context
of
their
tectonic
importance
in
a
common
reference
frame
with
respect
to
Eurasia’s
coeval
paleopoles.
Key
factors
that
play
an
important
role
in
determining
the
reliability
of
a
paleomagnetic
result
for
utilization
in
tectonic
studies
have
been
taken
into
consideration
and
include
the
absence
of
evidence
of
remagnetization,
which
is
a
feature
common
to
many
rocks
in
this
region.
Overall,
the
Cretaceous
paleomagnetic
data
from
the
South
China
Block
show
that
the
present
geo-
graphic
position
of
the
South
China
Block
has
been
relatively
stable
with
respect
to
Eurasia
since
the
mid-Cretaceous
and
that
the
paleomagnetically
detected
motion
of
a
coherent
lithospheric
block
must
be
based
on
the
representative
data
obtained
from
different
specific
localities
across
the
block
in
order
to
separate
more
localized,
smaller
scale
deformation
from
true
lithosphere
scale
motion
(translation
and/or
rotation)
of
a
tectonic
block.
Cretaceous
to
early
Tertiary
paleomagnetic
data
from
the
Indochina–Shan
Thai
Block
reveal
complex
patterns
of
intra-plate
deformation
in
response
to
the
India–Eurasia
collision.
Paleomagnetically
detected
motions
from
the
margins
of
tectonic
blocks
are
interpreted
to
mainly
reflect
displacement
of
upper
crustal
blocks
due
to
folding
and
faulting
processes.
Rigid,
lithosphere
scale
block
rotation
is
not
neces-
sarily
supported
by
the
paleomagnetic
data.
The
paleomagnetic
results
from
areas
east
and
south
of
the
Red
River
fault
system
suggest
that
this
major
transcurrent
fault
system
has
had
a
complicated
slip
history
through
much
of
the
Cenozoic
and
that
it
does
not
demarcate
completely
non-rotated
and
significantly
rotated
parts
of
the
crust
in
this
area.
However,
most
paleomagnetic
results
from
areas
east
and
south
of
the
Red
River
fault
system
at
the
latitude
of
Yunnan
Province
are
consistent
with
a
very
modest
(about
800
km+−),
yet
paleomagnetically
resolvable
southward
component
of
latitudinal
translation.
Accord-
ingly,
given
the
difficulty
in
separating
actual
lithosphere-scale
plate
motions
from
those
of
relatively
thin,
upper
crustal
blocks,
we
advocate
extreme
caution
in
interpreting
paleomagnetic
data
from
regions
such
as
Indochina
where
block
interaction
and
strong
deformation
are
known
to
have
occurred.
© 2011 Elsevier Ltd. All rights reserved.
1.
Introduction
The
tectonic
history
of
the
Southeast
Asia
region
has
attracted
the
attention
of
numerous
geoscientists
for
over
a
century.
Active
tectonic-geodynamic
processes
have
affected
the
region
in
a
∗
Corresponding
author.
Tel.:
+84
0913
222
102;
fax:
+84
4
37754797.
addresses:
(T.C.
Cung),
(J.W.
Geissman).
1
Now
at:
Department
of
Geosciences,
The
University
of
Texas
at
Dallas,
ROC
21,
800
West
Campbell
Road,
Richardson,
TX
75080-3021,
United
States.
Tel:
+1
972
883
2454;
fax:
+1
972
883
2537.
prolonged
and
complicated
fashion.
These
include
the
subduc-
tion
of
the
Indo-Australian
plate
under
the
Eurasia
plate
along
the
Indonesia
arc;
the
India–Eurasia
collision
and
different
intra-plate
deformation
processes
associated
with
the
formation
and
growth
of
the
Tibetan
Plateau.
The
Southeast
Asian
region
is
considered
a
natural
laboratory
for
active
tectonic
and
geodynamic
processes,
and
thus
can
be
used
as
an
analog
for
studying
more
ancient
tec-
tonic
processes.
There
are
two
general
schools
of
thought
regarding
the
effects
of
the
collision
between
India
and
Eurasia
on
the
subsequent
tectonic
history
of
eastern
and
southeast
Asia.
Propo-
nents
of
extrusion
tectonics
suggest
that
convergence
between
the
Indian
subcontinent
and
the
Eurasian
plate
was
mainly
accom-
modated
by
east–southeast
directed
translation
and
rotation
of
0264-3707/$
–
see
front
matter ©
2011 Elsevier Ltd. All rights reserved.
doi:
10.1016/j.jog.2011.11.008
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
2 T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx
Fig.
1.
Generalized
tectonic
framework
map
of
Southeast
Asia,
modified
from
Leloup
et
al.
(2001)
and
Takemoto
et
al.
(2005).
Arrows
adjacent
to
several
major
structures
show
overall
sense
of
shear
prior
to
∼16
Ma
along
these
structures.
large-scale,
discrete
continental
lithospheric
blocks
such
as
‘Sun-
daland’
(i.e.
Indochina,
Shan-Thai,
the
southwest
East
Vietnam
Sea,
and
southwest
Borneo),
South
China,
and
Tibet
along
major
left-
lateral
strike-slip
faults
(Tapponnier
et
al.,
1982,
1986;
Peltzer
and
Tapponnier,
1988;
Replumaz
and
Tapponnier,
2003)
(Fig.
1).
In
con-
trast,
other
workers
argue
that
crustal
shortening
and
thickening
in
the
Himalaya
and
Tibet
is
the
principal
mechanism
for
accommo-
dating
this
collision
(Dewey
et
al.,
1989;
England
and
Houseman,
1989;
England
and
Molnar,
1990).
One
major
consequence
pre-
dicted
by
both
models,
however,
is
a
large-magnitude
clockwise
rotation
of
Sundaland,
which
behaved
either
as
a
rigid
lithospheric
block
(a
basic
tenet
of
the
extrusion
model)
or
as
a
series
of
upper-
crustal
blocks
that
were
translated
southeastward
along
laterally
continuous,
north–south–trending
dextral
shear
zones
and
rotated
in
a
clockwise
sense
(as
in
crustal
shortening
models).
Over
the
past
few
decades,
paleomagnetic
results
from
rocks
of
different
ages
and
origins
from
the
Southeast
Asian
region
have
increased
both
in
quantity
and
quality,
and
the
data
obtained
contribute
to
elucidating
the
tectonic
history
of
this
region
over
time,
by
providing
increasingly
accurate
paleogeographic
reconstructions
of
lithosphere-scale
and
smaller
blocks
that
were
welded
together
as
microcontinents
to
form
the
Eurasian
conti-
nent
(Fig.
2).
However,
the
interpretation
of
paleomagnetic
results
from
an
actively
deforming
region
such
as
Southeast
Asia
is
not
straightforward,
because
early
acquired,
essentially
primary
magnetizations
may
be
modified
by
subsequent
tectonic
effects,
involving
enhanced
fluid
migration,
increased
burial
and
thus
enhanced
temperatures,
penetrative
deformation,
as
well
as
other
processes
(Lowrie
et
al.,
1986;
McCabe
and
Elmore,
1989;
Fuller
et
al.,
1991;
Gillett
and
Geissman,
1993;
Pares
et
al.,
1999;
Van
der
Voo
and
Torsvik,
2011).
Paleomagnetically
detected
rotations,
as
documented
by
discrepancies
or
discordances
in
declination
between
observed
and
expected
(or
“reference”)
declinations
may
sometimes
reflect
spatially
localized
components
of
deformation
related
to
shear
zones
(Ron
et
al.,
1984;
Jackson
and
Molnar,
1990),
differential
shortening
within
thrust
sheets
(Stamatakos
and
Hirt,
1994;
Roperch
et
al.,
2000;
Sussman
et
al.,
2004;
Pueyo
et
al.,
2004),
or
arc
related
deformation
(MacDonald,
1980;
Minyuk
and
Stone,
2009
).
Therefore,
rigid
body,
internally
coherent
rotations
of
plates,
or
microplates,
cannot
always
be
assumed
on
the
basis
of
the
data
available.
This
paper
synthesizes
the
available
paleomagnetic
data
from
Cretaceous
to
Paleogene
continental
red
bed
formations
from
the
Indochina
and
South
China
regions
obtained
in
several
studies
by
different
researchers
and
evaluates
their
tectonic
importance,
especially
paleomagnetically
detected
deformation
(specifically
rotation
and
translation)
of
crustal
elements
that
is
likely
related
to
the
India–Eurasia
collision
during
the
Cenozoic.
Space
does
not
allow
us
to
focus
attention
on
the
details
of
the
accuracy
and
reliability
of
each
specific
paleomagnetic
data
set;
rather,
we
con-
centrate
on
the
tectonic
interpretation
of
these
data,
and
consider
such
factors
as
the
origin
and
nature
of
magnetization
characteris-
tic
of
the
rocks
examined
(e.g.,
primary
or
secondary,
i.e.,
the
extent
of
possible
remagnetization),
the
age
of
the
rock
formation,
and
the
effects
that
tectonic
deformation
may
have
played
in
defining
the
tectonic
importance.
The
relative
rotation
and
translation
of
any
structural
block
or
domain
that
have
been
identified
on
the
basis
of
paleomagnetic
directions
from
rocks
located
within
that
block
are
determined
by
comparing
the
observed
directions
with
the
coeval
expected
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx 3
Table
1
Apparent
Polar
Wander
Path
for
Eurasia
derived
by
Besse
and
Courtillot
(1991).
Age
(Ma)
(
◦
N)
(
◦
E)
A
95
Age
(Ma)
(
◦
N)
(
◦
E)
A
95
Note
10
84.1
149.1
2.3
110
73.3
206.5
5.1
20
82.3 147.6 3.2
120
74.8
210.9
4.1
30
81.0
132.8
2.7
130
75.2
205.8
5.0
40
80.2
145.4
3.8
140
71.6
173.0
10.4
50
77.9
149.0
4.3
150
70.0
157.8
6.7
60
78.5
178.7
3.9
160
68.8
154.9
6.0
70
77.2
192.4
4.1
170
63.3
120.7
3.0
80
76.2
198.9
3.4
180
64.2
116.7
2.7
90
76.7 200.1 3.5 190
66.7
109.0
3.9
100
76.7
197.1
5.4
200
67.3
111.6
6.7
Mean
Eocene
poles
79.8
143.1
3.3
30–50
Ma
poles
Mean
K2
poles
77.2
193.9
2.0
60–100
Ma
poles
Mean
K1
poles
74.3
198.1
6.0
110–140
Ma
poles
Mean
K
poles
75.9
196.0
2.5
60–140
Ma
poles
Mean
J3–K
poles
75.4
186.6
3.6
60–160
Ma
poles
Mean
J3–K1
poles
73.7
181.8
6.7
110–160
Ma
poles
directions
of
a
reference
block
or
continent
derived
from
an
Appar-
ent
Polar
Wander
Path
(APWP)
that,
ideally,
is
well
determined
for
the
appropriate
geologic
time
interval
in
question.
Besse
and
Courtillot
(1991,
2002)
have
derived
synthetic
APWPs
for
the
Eurasia
continent
from
200
Ma
to
present
with
considerably
high
precision.
In
addition,
several
studies
have
contributed
to
the
inde-
pendent
development
of
an
APWP
for
the
South
China
block
itself
(e.g.,
Enkin
et
al.,
1992;
Chen
et
al.,
1993;
Hankard
et
al.,
2005;
Sun
et
al.,
2006;
Zhu
et
al.,
2006;
Tsuneki
et
al.,
2009),
therefore
the
paleomagnetic
data
from
rocks
of
the
Indochina
and
South
China
blocks
discussed
in
this
paper
will
be
compared
with
the
expected
directions
calculated
from
this
APWP
for
certain
geologic
time
periods
(Table
1)
to
evaluate
their
tectonic
significance.
2.
Cretaceous
paleomagnetic
results
of
the
South
China
Block
According
to
Hsu
et
al.
(1988),
the
South
China
Block
consists
of
two
micro-continents—the
Yangtze
Craton
in
the
northwest
and
the
Hoa
Nam
Block
in
the
southeast
(Fig.
1).
These
two
micro-continents
were
welded
together
during
subduction
of
the
Fig.
2.
Simplified
tectonic
framework
digital
elevation
map
of
the
Indochina
and
South
China
regions
and
the
observed
declinations
of
selected
Cretaceous
rock
formations
compared
with
expected
declination
values.
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
4 T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx
60
50
40
30
20
10
0
-10
-20
-30
-40
-50
Rotation Magnitude, in degrees
Locality Latitude, N
19
20
21
22
23
24
25
27
29
31
32
Mean, Early
Cretaceous (K1) poles
Mean, Late Cretaceous (K2) poles
Mean, Cretaceous poles
o
(clockwise)
(counterclockwise)
Fig.
3.
Relative
rotation
of
elements
of
South
China
tectonic
block,
as
a
function
of
latitude
of
the
sampling
area,
with
respect
to
Eurasia.
The
stars
represent
the
relative
rotation
of
South
China
Block
calculated
from
the
mean
of
paleomagnetic
poles
for
the
Early
Cretaceous,
the
Late
Cretaceous,
and
the
entire
Cretaceous
Period.
Vertical
bars
represent
the
uncertainty
of
each
result,
as
represented
by
˛
95
values.
paleo-Pacific
plate
under
the
Eurasia
plate
in
late
Mesozoic
time,
along
the
Jiangnan
suture
zone,
which
exposes
of
Mesoprotero-
zoic
and
Neoproterozoic
low-grade
metamorphic
rocks.
Xu
(1993),
however,
suggests
that
the
entire
eastern
part
of
the
Chinese
land-
mass
was
dominated
by
a
Mesozoic
sinistral
shear
system.
The
Xu
(1993)
hypothesis
is
supported
by
isotopic
and
paleomagnetic
data
from
Jurassic
and
Cretaceous
intrusions
that
are
widely
exposed
in
the
southeast
part
of
the
South
China
Block
(Gilder
et
al.,
1996).
There
is
general
consensus
that
by
the
Late
Jurassic
the
South
China
Block
was
already
accreted
to
the
North
China
Block
along
the
Qinling
suture
belt,
forming
the
stable
Eurasia
continent.
Since
the
early
1980s,
paleomagnetic
studies
have
been
carried
out
on
Mesozoic
and
Cenozoic
rock
formations
in
China,
and
these
data
have
facilitated
the
construction
of
overall
well-defined
Apparent
Polar
Wander
Paths
(APWP)
for
the
South
China
and
North
China
blocks
from
the
Late
Permian
to
the
present.
A
general
comparison
of
these
APWPs
with
the
APWP
for
the
Eurasian
continent
shows
that,
since
the
Cretaceous,
the
South
China
and
North
China
blocks
have
remained
relatively
stable
with
respect
to
the
Eurasia
plate
(
Enkin
et
al.,
1992).
The
India–Eurasia
collision
during
the
Cenozoic
has
not
significantly
distorted
the
South
China
and
North
China
blocks
relative
to
one
another
and
to
Eurasia
(Enkin
et
al.,
1992;
Chen
et
al.,
1993).
Paleomagnetic
data
from
Cretaceous
rock
formations
of
the
South
China
Block
(listed
in
Table
2)
show
that,
among
23
studies
at
generally
separate
localities,
only
six
provide
evidence
for
localities
affected
by
a
combination
of
the
relative
rotation
and
latitudinal
translation,
and
these
data
mainly
come
from
Upper
Cretaceous
to
Eocene
continental
red
beds.
For
six
other
localities,
only
relative
rotation
has
been
found
and
two
other
sites
show
only
latitudinal
translation.
The
relative
rotation
and
latitudinal
translation
data
are
summarized
in
Figs.
3
and
4.
A
comparison
of
Early
Cretaceous,
Late
Cretaceous
and
overall
Cretaceous
mean
paleopoles
of
the
South
China
Block
to
the
corre-
sponding
paleopoles
of
the
Eurasia
continent
shows
no
significant
rotation
nor
latitudinal
translation
of
the
South
China
Block
overall
relative
to
the
Eurasia
continent.
This
further
confirms
the
conclu-
sion
of
previous
workers
(e.g.,
Enkin
et
al.,
1992;
Chen
et
al.,
1993;
Hankard
et
al.,
2005;
Sun
et
al.,
2006;
Zhu
et
al.,
2006).
We
inter-
pret
the
relative
rotation
and
translation
that
is
implied
by
data
from
some
localities
to
reflect
local
deformation
of
the
upper
crust,
rather
than
motion
of
the
entire
lithospheric
block.
This
interpre-
tation
appears
to
be
consistent
with
the
observation
that,
at
least
for
some
localities,
larger
magnitudes
of
rotation
have
been
sug-
gested
in
younger
rocks
(e.g.,
Upper
Cretaceous
to
Eocene
strata),
yet
older,
underlying
rock
formations
have
been
less
deformed
by
20
10
0
-10
-20
Latitudinal Translation, in degrees
Locality Longitude, E
Mean, Early
Cretaceous (K1) poles
Mean, Late Cretaceous (K2) poles
Mean,
Cretaceous poles
o
(southward)
(northward)
30
25
15
5
-5
-15
-25
98
100
104 106
108 110
112
114
116
118
120
Fig.
4.
Latitudinal
translation
of
elements
of
the
South
China
block
as
a
function
of
longitude
of
the
sampling
area
with
respect
to
Eurasia.
The
stars
represent
the
relative
translation,
in
degrees,
of
parts
of
the
South
China
Block
calculated
from
the
mean
of
paleomagnetic
poles
for
the
Early
Cretaceous,
the
Late
Cretaceous,
and
the
entire
Cretaceous
Period.
Vertical
bars
represent
the
uncertainty
of
each
result,
as
represented
by
˛
95
values.
vertical
axis
rotation.
There
are
alternative
explanations
for
such
seemingly
disparate
data
sets.
Older
rocks
could
have
been
system-
atically
remagnetized
at
a
time
younger
than
the
age
of
overlying
rocks
preserving
primary
magnetizations
that
imply
rotations.
An
accurate
paleomagnetic
assessment
of
the
displacement
of
a
large-scale
lithospheric
block
should,
in
principle,
be
based
on
data
from
several
well-distributed
study
localities,
as
results
from
deformed
or
deforming
areas,
typically
at
the
margin
of
cratonic
block,
may
likely
be
unrepresentative
of
the
stable
interior
(e.g.,
Van
der
Voo,
1993).
Data
from
areas
that
have
potentially
been
affected
by
more
local
scale
tectonism
must
be
considered
with
great
caution
when
considering
their
incorporation
into
a
grand
mean
paleomagnetic
pole
determination
for
a
craton.
Furthermore,
the
age
of
the
rocks
examined,
as
well
as
the
age
of
the
magne-
tization(s)
that
are
characteristic
of
the
rocks
examined
must
be
known
for
the
most
robust
comparisons
with
well-dated
reference
paleomagnetic
poles.
Finally,
as
more
and
more
studies
are
demon-
strating,
the
effects
of
sediment
compaction
on
the
inclination
of
the
remanence
preserved
in
sedimentary
rocks
during
what
are
typically
prolonged
and
complicated
diagenetic
processes
can
be
significant
(refs).
Inclination
flattening
factors
(f),
with
f
being
the
ratio
of
tan
(Io)/tan
(If),
where
Io
is
the
observed
inclination
and
If
is
the
decompacted
or
deflattened
inclination,
can
be
approx-
imated
using
both
laboratory-based
approaches
(e.g.,
Bilardello
and
Kodama,
2009,
2010)
and
one
involving
examination
of
the
elongation
bias
in
observed
paleomagnetic
vectors
relative
to
an
expected
long-term
geocentric
axial
dipole
field
model
(Tauxe
and
Kent,
2004).
For
red
beds,
for
example,
f
values
typically
vary
from
about
0.78
(e.g.,
Donohoo-Hurley,
2011;
Donohoo-Hurley
et
al.,
in
preparation
)
to
about
0.52
(e.g.,
Kent
and
Olsen,
2008).
Not
all
“ref-
erence”
paleomagnetic
poles
that
are
used
in
the
present
overview,
or
any
similar
assessment,
either
include
only
those
data
from
sed-
imentary
rocks
that
have
been
adequately
corrected
for
inclination
shallowing
or
are
based
only
on
data
from
igneous
rocks
(unaf-
fected
by
inclination
shallowing).
Consequently,
inferences
based
on
the
inclinations
of
paleomagnetic
data
from
sedimentary
rocks
that
we
discuss
below
must
be
treated
with
caution,
as
it
is
likely
that
current
estimates
of
latitudinal
translation
may
be
in
greater
error
than
that
simply
based
on
the
estimated
dispersion
of
the
population
of
data
used
to
determine
a
mean
inclination.
3.
Cretaceous
paleomagnetic
results
from
Vietnam
Since
1992,
several
paleomagnetic
studies
have
been
carried
out
by
the
first
author
of
this
contribution,
as
well
as
others,
on
different
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx 5
Table
2
Cretaceous–Eocene
paleomagnetic
results
of
the
South
China
block.
N
Location
Age
(Ma)
Observed
VGP
Expected
VGP
Rotation
Translation
Significance
Reference
(
◦
N)
(
◦
E)
(
◦
N)
(
◦
E)
A
95
(
◦
N)
(
◦
E)
R
±
R
±
South
China
block
1
25.7
101.3
E
72.3
218.4
4.5
79.8
143.1
8.3
±
6.1
16.3
±
5.6
Y/Y
(13)
2
26.1 101.7 E
70.1 224.6
4.9
79.8
143.1
9.1
±
6.5
19.2
±
5.9
Y/Y
(13)
3
25.7
102.1
K2–E
61.8
192.2
10.5
77.2
193.9
16.6
±
11.6
2.2
±
10.7
Y/N
(14)
4
25.9
101.8
K2–E
65.6
203.0
2.6
77.2
193.9
11.3
±
3.5
5.7
±
3.2
Y/Y
(14)
5
25.0
116.4
K2
67.9
186.2
9.2
77.2
193.9
10.1
±
10.9
−3.5
±
9.4
N/N
(4)
6
26.0
117.3
K2
65.1
207.2
5.0
77.2
193.9
13.1
±
6.0
4.8
±
5.4
Y/N
(2)
7
23.1
113.3
K2
56.2
211.5
3.9
77.2
193.9
20.8
±
4.6
9.9
±
4.4
Y/Y
(2)
8
24.4 112.3 K2
66.0 221.5 3.4
77.2
193.9
9.3
±
4.1
10.8
±
4.0
Y/Y
(15)
9
30.0 102.9 K2
72.8 241.1
6.6
77.2
193.9
−2.8
±
7.3
12.3
±
6.9
N/Y
(9)
10
32.0
119.0
K2
76.3
172.6
10.3
77.2
193.9
−0.7
±
13.6
−4.8
±
10.5
N/N
(12)
11
30.8
118.2
K2
83.8
200.3
14.6
77.2
193.9
−7.7
±
17.4
1.6
±
14.7
N/N
(16)
12
25.0
101.5
K
49.2
178.0
11.4
75.9
196.0
30.3
±
13.2
−4.2
±
11.6
Y/N
(3)
13
30.1
103.0
K
76.3
274.5
11.1
75.9
196.0
−14.0
±
11.9
11.9
±
11.4
Y/Y
(11)
14
22.2
114.2
J3–K
78.2
171.9
10.6
75.4
186.6
−4.2
±
12.6
−2.2
±
11.1
N/N
(1)
15
30.0
102.9
K1
74.5
229.0
4.0
74.3
198.1
−4.4
±
8.0
7.2
±
7.3
Y/N
(10)
16
18.9
109.4
K1
83.2
143.0
9.8
74.3
198.1
−12.5
±
12.5
−6.0
±
11.5
N/N
(17)
17
22.7
108.7
K1
86.5
26.4
10.0
74.3
198.1
−20.8
±
12.7
−1.1
±
11.6
Y/N
(2)
18
26.0 117.3 K1
66.9
221.4
5.4
74.3
198.1
6.2
±
8.9
8.9
±
8.1
N/Y
(5)
19
26.5
102.4
K1
81.5
220.9
7.1
74.3
198.1
−9.0
±
10.2
1.7
±
9.3
N/N
(6)
20
26.8
102.5
K1
69.0
204.6
4.3
74.3
198.1
4.8
±
8.0
3.5
±
7.4
N/N
(6)
21
27.9
102.3
K1
77.4
196.2
14.5
74.3
198.1
−3.2
±
17.5
−1.1
±
15.8
N/N
(7)
22
27.9
102.3
K1
85.2
241.7
3.5
74.3
198.1
−13.9
±
7.6
1.0
±
7.0
Y/N
(13)
23
29.7
120.3
K1
77.1
227.6
5.5
74.3
198.1
−4.5
±
9.4
6.6
±
8.1
N/N
(8)
Mean
K1
poles
(13–23): 80.0 216.1
5.4
74.3
198.1
−7.1
±
8.8
2.2
±
8.1
N/N
Mean
K2
poles
(3–11):
69.2
203.6
6.6
77.2
193.9
8.4
±
7.5
3.8
±
6.9
Y/N
Mean
K
poles
(3–23):
74.2
204.9
5.0
75.9
196.0
1.4
±
6.1
2.6
±
5.6
N/N
Note:
Sign.
=
Significance
(Y:
Yes,
N:
No),
Ref.
=
Reference,
K1
=
Early
Cretaceous,
K2
=
Late
Cretaceous,
K
=
Cretaceous,
J3–K
=
Late
Jurassic–Cretaceous,
K2–E
=
Late
Cretaceous–Eocene,
E
=
Eocene.
Rotation
and
latitudinal
translation
were
calculated
at
each
study
locality
following
Butler
(1992);
negative
(positive)
sign
indicates
CCW
(CW)
rotation
and
southward
(northward)
translation,
respectively.
Expected
VGPs
are
calculated
from
Eurasian
poles
(Table
1)
derived
by
Besse
and
Courtillot
(1991).
(1)
=
Chan
(1991),
(2)
=
Gilder
et
al.
(1993),
(3)
=
Funahara
et
al.
(1992),
(4)
=
Hu
et
al.
(1990),
(5)
=
Zhai
et
al.
(1992),
(6)
=
Huang
and
Opdyke
(1992a),
(7)
=
Zhu
et
al.
(1988),
(8)
=
Lin
(1984),
(9)
=
Enkin
et
al.
(1991a),
(10)
=
Enkin
et
al.
(1991b),
(11)
=
Otofuji
et
al.
(1990),
(12)
=
Kent
et
al.
(1986),
(13)
=
Yoshioka
et
al.
(2003),
(14)
=
Otofuji
et
al.
(1998),
(15)
=
Hsu
(1987),
(16)
=
Gilder
et
al.
(1999),
(17)
=
Li
et
al.
(1995).
rock
units
of
Cretaceous
age
in
Vietnam.
The
results
of
these
studies
have
been
published
in
Vietnamese
and
international
journals
(Chi,
1996,
2001;
Chi
et
al.,
1998,
1999,
2000;
Chi
and
Dorobek,
2004).
The
second
author
is
in
the
processes
of
preparing
a
contribution
on
a
collection
of
Cretaceous
red
beds
obtained
in
2009
and
some
preliminary
results
are
presented
here.
The
results
of
all
of
these
studies
are
summarized
below;
information
on
individual
site
data
and
characteristics
of
the
paleomagnetism
of
each
rock
unit
is
in
the
original
papers.
3.1.
Northwestern
Vietnam
Ten
sites
with
76
oriented
core
samples
were
collected
from
Late
Jurassic
and
Cretaceous
extrusive,
intrusive,
and
red
bed
rocks
from
the
Tu
Le
Depression
and
Song
Da
Terrane,
situated
just
to
the
south
of
the
Red
River
fault
(Figure
1
of
Chi
et
al.,
2000).
The
analysis
of
the
rock
magnetic
properties
and
the
response
to
progressive
AF
and
thermal
demagnetization
of
rock
samples
reveals
that
the
principal
remanence
carrier
in
the
extrusive
and
intrusive
rocks
sampled
is
nearly
pure
to
low
Ti
magnetite
and
that
of
red
beds
sampled
is
hematite
(Chi
et
al.,
2000).
The
paleomagnetic
results
(Table
3)
are
interpreted
to
suggest
that
the
area
studied
in
northwest
Vietnam
has
not
been
significantly
rotated
nor
translated
in
a
latitudinal
sense
relative
to
the
South
China
Block
or
the
Eurasia
continent
since
the
Cretaceous
(Table
5,
Figs.
5
and
6).
The
results
are
consis-
tent
with
those
reported
by
Huang
and
Opdyke
(1993),
from
Upper
Cretaceous
red
bed
strata
near
Xiaguan,
in
southwestern
Yunnan,
China,
situated
adjacent
to
the
Red
River
fault.
Chi
et
al.
(2000)
determined
a
Late
Jurassic–Cretaceous
paleomagnetic
pole
for
the
northwest
region
of
Vietnam,
which
is
located
at
83.9
◦
N,
233.1
◦
E
(A
95
=
11.9
◦
).
This
pole
is
statistically
indistinguishable
from
the
Late
Cretaceous
paleomagnetic
pole
for
the
Xiaguan
area
(83.6
◦
N,
152.7
◦
E,
A
95
=
10
◦
)
reported
by
Huang
and
Opdyke
(1993),
but
both
of
these
results
are
associated
with
relatively
high
dispersion.
The
two
reported
poles
are
also
indistinguishable
from
Cretaceous
paleomagnetic
poles
for
the
South
China
block
and
Eurasia
con-
tinent
at
95%
confidence
level,
which
further
corroborates
Huang
and
Opdyke’s
(1993)
conclusion
that
the
Red
River
fault
does
not
demarcate
unrotated
and
significantly
rotated
regions
(Huang
and
Opdyke,
1993).
More
recently,
Takemoto
et
al.
(2005)
reported
data
from
the
Yen
Chau
Formation,
consisting
of
mid-Cretaceous
red
bed
that
are
part
of
the
Song
Da
Terrane
in
northwest
Vietnam.
Fifteen
sites,
with
six
to
ten
hand
samples
at
each
site,
were
collected
at
Yen
Chau
and
Lai
Chau
localities
along
the
road
No.
6
leading
from
60
50
40
30
20
10
0
-10
-20
-30
-40
Rotation Magnitude, in degrees
Locality Latitude, N
(clockwise)
(counter-
clockwise)
21
11
12
13 14
15
16
17
18
19
20
22
23
24
25
26 27
Yongping (K1)
Yunlong
(K2)
Lan
ping
(K2)
Xiaguan (K2)
Northern Vietnam (
J3-K)
Khorat
Plateau (J3-K1)
Southern
Vietnam (K)
Shan Plateau (
J3-K)
Simao Terrane
Mengla (Eocene)
Mengla (K2)
Jinggu (K2)
Jinggu (K1)
70
80
90
100
110
120
o
Lanping
(Eocene)
Fig.
5.
Relative
rotation
of
elements
of
the
Indochina-Shan
Thai
terranes,
as
a
func-
tion
of
the
latitude
of
the
sampling
area,
with
respect
to
Eurasia.
Vertical
bars
represent
the
uncertainty
of
each
result,
as
represented
by
˛
95
values.
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
6 T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx
Table
3
Paleomagnetic
results
of
Late
Jurassic–Cretaceous
rocks
from
northwestern
Vietnam.
Site
Location
Rock
type
Age
n/N
ChRM
direction
VGP
Lat.
(
◦
N)
Long
(
◦
E)
D
g
(
◦
)
I
g
(
◦
)
D
s
(
◦
)
I
s
(
◦
)
˛
95
k
Lat
(
◦
N)
Long
(
◦
E)
GP
21.15
104.65
Volcanic
tuff
J3–K
5/5
37.2
56.1
–
–
9.6
34.0
54.3
161.3
BH1
21.47
104.38
Rhyolitic
tuff
J3–K
6/6
357.8
34.7
–
–
2.6
669.5
86.6
321.8
BH2
21.47
104.38
Rhyolitic
porphyry
J3–K
7/7
353.8
26.9
–
–
6.2
94.5
80.4
323.8
TL
21.69 104.45 Volcanic
ash
J3–K
8/8
5.6
49.5
–
–
7.9
24.1
80.4
135.1
PT
22.53
103.28
Sandstone
K
6/7
338.6
48.8
–
–
12.7
14.2
69.7
37.7
NTH
21.48
104.42
Rhyolite
K
6/6
358.5
23.4
–
–
5.1
170.3
80.3
293.4
SR
21.28
104.70
Redbed
siltstone
K
9/9
21.1
−30.6
–
–
7.8
44.9
46.8
254.9
22.3
8.4
7.2
52.6
62.3
230.6
YC
21.05
104.27
Redbed
siltstone
K2
12/12
188.0
−36.5
–
–
14.9
9.4
82.5
199.1
192.6 −15.6 14.7 9.7 72.1 239.8
QH
22.36 103.78
Granite
K2–Pg
8/8
347.7
18.3
–
–
9.2
37.5
72.3
328.0
OQ
22.37
103.73
Granite
K2–Pg
7/8
18.9
21.9
–
–
4.6
88.9
68.7
223.0
Mean:
10
–
–
4.9
31.2
13.1
14.5
83.9
233.1
Note:
N
=
total
number
of
samples;
n
=
number
of
samples
used
in
calculation
of
mean
directions;
ChRM
=
characteristic
remanent
magnetization;
D
g
,
I
g
=
geographic
(in
situ)
declination
and
inclination;
D
s
,
I
s
=
stratigraphic
(tilt
corrected)
declination
and
inclination;
˛
95
=
radius
of
95%
confidence
circle;
k
=
precision
parameter;
VGP
=
Virtual
Geomagnetic
Pole;
J3–K
=
Late
Jurassic-Cretaceous;
K2–Pg
=
Late
Cretaceous–Paleogene;
K2
=
Late
Cretaceous.
Hoa
Binh
to
Son
La
and
Lai
Chau.
Thirteen
sites
yield
a
positive
fold
test
and
give
a
grand
mean
mid-Cretaceous
paleomagnetic
direction
(D
=
6.4
◦
,
I
=
32.0
◦
,
˛
95
=
8.5
◦
)
that
corresponds
to
a
paleo-
magnetic
pole
located
at
82.9
◦
N,
220.7
◦
E
(A
95
=
6.9
◦
).
Their
results
are
consistent
with
results
reported
by
Chi
et
al.
(2000),
(Table
5,
Figs.
4
and
5).
On
the
basis
of
a
paleomagnetic
collection
involving
ten
separate
localities,
with
6–19
sites
collected
per
locality
and
seven
to
15
samples
collected
from
each
site,
Geissman
(unpub-
lished
data,
2011)
concluded
that,
overall,
the
paleomagnetic
data
from
this
area
are
consistent
with
those
reported
by
Takemoto
et
al.
(2005)
,
and
that,
depending
on
the
locality
investigated,
the
rema-
nence
in
these
mid-Cretaceous
strata
is
heavily
contaminated
by
a
relatively
recent,
post-folding
magnetization
(Fig.
7).
Overall,
the
paleomagnetic
results
from
the
three
areas
located
along
and
immediately
southwest
of
the
Red
River
fault
system
in
northern
Vietnam
suggest
that
the
fault
does
not
demarcate
non-
rotated
and
significantly
rotated
crust.
If
elements
of
the
Indochina
Block
had
been
extruded
by
a
significant
amount,
in
a
southeast
directed
fashion,
as
suggested
by
proponents
of
the
extrusion
tec-
tonics,
it
must
have
taken
place
on
some
other
faults
located
farther
to
the
southwest
of
the
Red
River
fault.
3.2.
Southern
Vietnam
Twenty
four
sites
with
a
total
of
163
core
samples
were
col-
lected
from
Cretaceous
volcanic,
intrusive
and
sedimentary
rocks
in
southern
Vietnam
(Chi
and
Dorobek,
2004).
The
distribution
of
VGPs
from
the
accepted
sites
(Table
4),
when
compared
with
20
10
0
-10
-20
Latitudinal Translation, in degrees
Locality Longitude, E
(southward)
(northward)
25
15
5
-5
-15
-25
98
100
104
106
108
96
97
99
101
102
105
107
Southern
Vietnam
Khorat Plateau
Northern
Vietnam
Simao Terrane
Mengla
(Eocene)
Lanping (Eocene)
Mengla (K2)
Lanping (K2)
Jinggu (K2)
Jinggu (K1)
Shan Plateau
Yongping (K1)
-30
-35
o
Fig.
6.
Relative
translation
of
the
Indochina-Shan
Thai
terranes,
as
a
function
of
the
longitude
of
the
sampling
area,
with
respect
to
Eurasia.
Vertical
bars
represent
the
uncertainty
of
each
determination,
as
represented
by
the
˛
95
values.
the
Eurasia
mean
Cretaceous
paleopole,
may
indicate
a
very
slight
southward
displacement
of
southern
Vietnam
(6.5
±
5.1
◦
),
yet
no
appreciable
rotation
since
the
Cretaceous
(Table
5,
Figs.
4
and
5).
Given
that
this
is
the
only
set
of
paleomagnetic
results
from
south-
ern
Vietnam
and
that
the
data
are
from
a
wide
range
of
rock
types,
this
result,
although
it
represents
the
only
data
available
from
southern
Vietnam,
should
be
considered
of
limited
importance.
The
available
paleomagnetic
data
from
Cretaceous
rocks
in
northwest
and
southern
Vietnam
may
support
some
degree
of
internal
deformation
of
this
region
in
response
to
the
India–Eurasia
collision,
but
the
distribution
of
the
data
remains
far
too
sparse
to
provide
firm
conclusions.
The
possible
southward
displace-
ment,
yet
insignificant
rotation
of
southern
Vietnam,
may
reflect
north–south
oriented
spreading
in
the
northern
part
of
South
China
Sea
with
the
development
of
a
major
right-lateral
transform
fault
system
that
extended
just
off
the
eastern
continental
margin
of
Vietnam
(Taylor
and
Hayes,
1980,
1983).
High
quality
paleomag-
netic
data
are
sorely
needed
from
Cretaceous
rocks
from
the
far
northeast
part
of
Vietnam,
east
of
the
Red
River
fault
system.
4.
Cretaceous
paleomagnetic
results
from
the
Indochina–Shan
Thai
Block
A
term
that
has
often
been
used
in
reference
to
tectonic
models
of
Cenozoic
deformation
in
the
Southeast
Asia
region,
and
referred
to
in
the
introduction,
is
the
‘Sundaland’
plate.
The
Sundaland
plate
is
defined
to
the
northeast
by
the
Red
River
fault,
to
the
west
by
the
Sagaing
fault
in
Myanmar,
to
the
east
by
the
Philippine
subduction
zone,
and
to
the
south
by
the
Indonesia
subduction
zone
(Fig.
1).
This
plate
includes
the
Shan-Thai
and
Indochina
blocks,
southwest
East
Vietnam
Sea,
Borneo
and
Malaya-Indonesia
islands.
Paleomag-
netic
data
from
farther
south
in
the
Sundaland
plate
(Fuller
et
al.,
1991;
Richter
and
Fuller,
1996)
were
used
to
evaluate
the
Cenozoic
tectonic
evolution
of
this
region
and
reflect
the
tectonic
complexity
of
the
Southeast
Asian
region.
Opposite
sense
rotations
with
dif-
ferent
magnitudes
of
rotation
have
been
observed
from
the
same
terrane
or
from
different
terranes.
Data
from
the
interior
part
of
Sundaland
are
supportive
of
some
magnitude
of
clockwise
rota-
tion,
although
counterclockwise
rotations
appear
to
characterize
the
Indonesian
peninsula
and
islands
located
in
the
southeastern
part
of
the
region.
The
Cretaceous
paleomagnetic
data
of
the
Shan-Thai
and
Indochina
blocks
obtained
over
the
past
two
decades
or
so
highlight
the
nature
and
potential
complexities
of
intraplate
deforma-
tion
due
to
the
impact
of
India–Eurasia
collision.
According
to
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx 7
Fig.
7.
Some
preliminary
paleomagnetic
results
from
Cretaceous
redbeds
in
northwest
Vietnam.
(a,
b)
Relatively
recent
road
construction
activities
have
resulted
in
abundant
road
exposures
of
relatively
fresh
bedrock
in
this
area.
(c–i)
Examples
of
response
to
progressive
demagnetization
by
Cretaceous
redbeds.
Orthogonal
demagnetization
diagrams
showing
the
endpoint
of
the
magnetization
vector
plotted
onto
the
horizontal
(filled
symbols)
and
vertical
(open
symbols)
planes
(Zijderveld,
1967).
Selected
demagnetization
steps
are
show
adjacent
to
vertical
projections.
All
diagrams
in
geographic
coordinates.
(c–e)
Demagnetization
results
showing
the
removal
of
a
north-
directed
and
steep
positive
inclination
(in
geographic
coordinates)
magnetization
followed,
at
high
laboratory
unblocking
temperatures,
a
magnetization
that
is
northwest-
directed
and
shallow
inclination
that,
in
stratigraphic
coordinates
is
north–northeast
directed
and
moderate
positive
in
inclination
and
is
interpreted
as
a
primary
remanence.
(f
and
g)
Demagnetization
results
showing
the
first-removal
of
a
north-directed
and
moderate
positive
inclination
magnetization,
followed
by
an
east-directed
and
shallow
magnetization.
Results
from
this
locality
are
interpreted
to
suggest
a
considerable
magnitude
clockwise
rotation,
that
is
inconsistent
with
other
data
from
northwest
Vietnam
and
likely
reflective
of
a
local
structural
feature.
(h
and
i)
Examples
of
results
where
a
moderate
negative
inclination
magnetization
predominates;
after
structural
correction
this
magnetization
is
south-directed
and
of
relatively
shallow
inclination,
and
thus
interpreted
as
a
reverse
polarity
primary
magnetization.
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
8 T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx
Table
4
Paleomagnetic
results
of
Cretaceous
rock
formations
from
southern
Vietnam.
Site
Location
Rock
type
St/Dp
n/N
ChRM
direction
VGP
Lat
(
◦
N)
Long
(
◦
E)
D
g
(
◦
)
I
g
(
◦
)
D
s
(
◦
)
I
s
(
◦
)
˛
95
k
s
(
◦
N)
s
(
◦
E)
A
95
8703
12.47
109.13
Rhyolitic
tuff
18/24
7/7
18.1
36.9
35.1
33.2
7.4
67.7
185.1
55.8
6.8
8705
12.29
109.21
Rhyolite
–
6/6
354.7
34.6
–
–
2.8
561.5
72.8
81.5
2.4
8706
12.20
109.21
Trachyriolite
34/18
5/5
2.5
37.3
16.9
44.8
3.0
661.1
155.0
68.7
3.0
8707
a
12.06 108.53 Dacite
–
4/5
65.7
34.0
–
–
16.7
31.3
183.6
26.6
14.4
8708
11.85
108.58
Shalestone
265/04
4/6
28.0
44.4
26.1
41.0
5.7
261.8
169.9
62.6
5.4
8709
11.76
108.51
Andesitic
tuff
254/06
6/10
24.5
40.6
21.2
35.0
13.2
26.8
175.6
68.3
11.5
8710
11.88
108.47
Red
Siltstone
295/15
6/6
12.7
36.8
14.5
22.0
11.5
34.6
198.8
75.8
8.8
8711
11.78
108.42
Dacite
07/23
6/7
349.1
40.1
9.8
43.2
1.8
999.9
141.8
73.7
1.8
8713
11.69
108.38
Red
Siltstone
281/06
7/9
21.3
41.9
20.4
35.7
7.9
58.9
173.5
68.8
7.0
PH
11.62 108.20 Red
Siltstone 266/18
7/7
13.1 51.3
8.8
33.9
4.2
207.8
157.8
79.0
3.6
NH
12.47 109.13
Rhyolitic
tuff
18/24
8/8
5.6
39.5
26.1
40.4
1.9
876.3
172.4
63.0
1.8
BD2
a
11.39
106.19
Granodiorite
–
8/8
70.7
26.4
–
–
12.1
22.0
185.5
21.2
9.7
BD1
11.39
106.15
Andesite
–
6/6
26.4
22.5
–
–
7.2
99.8
192.8
64.1
5.6
DL
11.90
108.45
Felsite
–
5/7
15.9
33.9
–
–
10.9
49.9
173.0
73.3
9.4
BN
11.80
109.11
Dacite
–
7/7
27.8
34.4
–
–
3.2
359.7
180.8
62.3
2.8
RR
12.33
109.20
Andesite
–
8/8
6.3
54.3
–
–
4.0
193.4
122.4
66.8
4.7
TR
12.31
109.19
Andesite
–
8/8
4.5
23.6
–
–
4.0
191.6
198.8
85.6
3.1
NT
11.27
108.73
Rhyolite
–
6/6
13.0
37.7
–
–
6.0
123.9
158.8
74.1
5.4
VT
10.35 107.07 Rhyolite
–
3/3
354.5
15.6
–
–
17.6
50.0
353.7
84.1
13.0
DC
12.88
109.38
Granite
–
6/6
13.6
26.3
–
–
5.4
96.8
193.5
76.7
4.3
CN
11.36
108.87
Granite
–
6/6
34.5
30.9
–
–
7.1
59.5
185.8
56.2
5.9
NS
10.68
105.08
Granite
–
7/8
155.7
–15.6
–
–
4.0
258.9
10.7
65.9
2.9
CT
10.37
105.02
Granodiorite
–
8/8
23.3
23.4
–
–
6.3
77.6
188.2
67.1
4.9
THI
a
10.56
107.08
Granite
–
4/6
315.9
6.8
–
–
7.9
136.7
11.1
45.7
5.6
Mean
of
21
sites: 21/24
11.5
35.3
14.5
33.3
6.3
26.7
171.1
74.2
5.9
Note:
St
=
bedding
strike,
Dp
=
bedding
dip,
n
=
number
of
samples
(sites)
used
in
calculation
of
mean
directions,
N
=
total
number
of
samples
(sites),
D
g
(I
g
)
=
geographic
declination
(inclination),
D
s
(I
s
)
=
stratigraphic
declination
(inclination),
˛
95
(A
95
)
=
circle
of
95%
confidence,
k
=
precision
parameter,
s
(
s
)
=
stratigraphic
latitude
(longitude).
a
Indicates
the
sites
which
were
not
included
in
the
mean
calculation.
models
proposed
for
the
quasi-rigid
extrusion
of
tectonic
ele-
ments
of
Southeast
Asia,
the
Indochina
Block
has
experienced
a
net
clockwise
rotation
of
about
40
◦
,
and
has
been
displaced
south-
ward
some
800–1000
km,
which
under
favorable
circumstances
is
resolvable
with
paleomagnetic
data,
along
the
sinistral
Red
River
and
Me
Kong
River
fault
systems
to
accommodate
defor-
mation
related
to
the
convergence
of
the
India–Eurasia
collision.
The
paleomagnetic
data
from
Upper
Jurassic
to
Lower
Cretaceous
sedimentary
rocks
from
the
Khorat
Plateau
(16.5
◦
N,
103.0
◦
E),
Thailand
(Yang
and
Besse,
1993)
are
cited
as
early
acquired
evi-
dence
in
support
of
this
model.
Based
on
a
comparison
with
five
selected
Late
Jurassic–Early
Cretaceous
paleopoles
from
the
South
China
Block,
Yang
and
Besse
(1993)
determined
that
the
Indochina
Block
has
rotated
about
14
◦
(14.2
±
7.1
◦
)
clockwise
and
was
dis-
placed
some
11
◦
southward
(11.5
±
6.7
◦
)
relative
to
the
South
China
Block
since
the
Cretaceous.
If
Late
Jurassic
to
Early
Creta-
ceous
reference
poles
for
the
Eurasian
continent
are
used
as
a
reference,
however,
the
estimated
magnitude
of
Khorat
Plateau
clockwise
rotation
is
less
(10.2
±
7.3
◦
)
and
the
estimated
magnitude
of
southward
displacement
is
insignificant
(3.4
±
6.9
◦
)
(Table
5,
Figs.
4
and
5).
As
noted
above,
the
selection
of
accurate
reference
paleomagnetic
poles
is
critical
for
reliable
tectonic
interpretation
Table
5
Cretaceous–Eocene
paleomagnetic
results
of
the
Indochina
Block.
Locality
Lat
(
◦
N)
Long
(
◦
E)
Age
Observed
VGP
Expected
VGP
Rotation
Translation
Significance
Ref.
(
◦
N)
(
◦
E)
A
95
(
◦
N)
(
◦
E)
R
±
R
±
Indochina
Block:
Song
Da
Terrane
21.7
103.9
K2
82.9
220.7
6.9
77.2
193.9
−7.0
±
7.6
2.7
±
7.1
N/N
(1)
Tu
Le
Depression
21.7
104.2
J3–K
83.9
233.1
11.9
75.4
186.6
−10.7
±
13.1
5.1
±
12.4
N/N
(2)
South
Vietnam
11.7
108.2
K
74.2
171.1
5.9
75.9
196.0
0.4
±
5.4
−6.5
±
5.1
N/Y
(3)
Khorat
Plateau
16.5
103.0
J3–K1
63.8
175.6
1.7
73.7
181.8
10.2
±
7.3
−3.4
±
6.9
Y/N
(4)
Shan-Thai
Block:
Simao
Terrane:
Lanping
26.5
99.3
E
14.5
169.7
10.9
79.8
143.1
76.5
±
12.6
9.9
±
11.4
Y/N
(5)
Mengla
23.5
100.7
E
13.2
172.2
5.4
79.8
143.1
76.7
±
6.9
8.8
±
6.4
Y/Y
(10)
Yunlong
25.8
99.4
K2
54.6
171.3
4.4
77.2
193.9
26.0
±
5.6
−7.0
±
4.9
Y/Y
(6)
Xiaguan
25.6
100.2
K2
83.6
152.7
10.0
77.2
193.9
−8.2
±
11.7
−5.3
±
10.2
N/N
(7)
Jinggu
23.4
100.9
K2
18.9
170.0
8.9
77.2
193.9
65.7
±
10.1
−3.9
±
9.1
Y/N
(7)
Mengla
21.6
100.4
K2
33.7
179.3
8.2
77.2
193.9
47.2
±
9.0
−0.4
±
8.5
Y/N
(7)
Lanping
25.8
99.4
K2
69.7
167.6
6.9
77.2
193.9
8.2
±
8.4
−7.5
±
7.1
N/Y
(9)
Yongping
25.5
99.5
K1
50.9
167.3
20.6
74.3
198.1
27.5
±
25.7
−11.1
±
21.5
Y/N
(8)
Jinggu
23.5
100.7
K1
−13.9
161.3
4.3
74.3
198.1
99.2
±
7.9
0.6
±
7.4
Y/N
(10)
Shan
Plateau
20.4
96.3
J3–K
46.4
190.6
3.5
75.4
186.6
29.1
±
5.2
7.8
±
4.0
Y/Y
(11)
Note:
Ref.
=
reference,
significance
(Y
=
Yes,
N
=
No).
K1
=
Early
Cretaceous,
K2
=
Late
Cretaceous,
K
=
Cretaceous,
J3–K
=
Late
Jurassic–Cretaceous,
J3–K1
=
Late
Jurassic–Early
Cretaceous,
E
=
Eocene.
Rotation
and
latitudinal
translation
were
calculated
at
each
study
locality
following
Butler
(1992);
negative
(positive)
sign
indicates
CCW
(CW)
rotation
and
southward
(northward)
translation,
respectively.
Expected
poles
are
calculated
(Table
1)
from
Eurasian
poles
derived
by
Besse
and
Courtillot
(1991).
(1)
=
Takemoto
et
al.
(2005)
,
(2)
=
Chi
et
al.
(2000),
(3)
=
Chi
and
Dorobek
(2004),
(4)
=
Yang
and
Besse
(1993),
(5)
=
Sato
et
al.
(2001),
(6)
=
Sato
et
al.
(1999),
(7)
=
Huang
and
Opdyke
(1993),
(8)
=
Funahara
et
al.
(1993),
(9)
=
Yang
et
al.
(2001),
(10)
=
Chen
et
al.
(1995),
(11)
=
Richter
and
Fuller
(1996).
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx 9
of
paleomagnetic
results
from
a
particular
area,
in
particular
when
magnitudes
of
rotation
and
latitudinal
translation
may
be
relatively
small.
Many
paleomagnetic
studies
have
been
carried
out
on
Cre-
taceous
to
Eocene
red
bed
formations
from
the
Lanping-Simao
Terrane
in
western
Yunnan,
China
(Huang
and
Opdyke,
1993;
Chen
et
al.,
1995;
Sato
et
al.,
1999,
2001;
Yang
et
al.,
2001;
Burchfiel
et
al.,
2007;
Geissman
et
al.,
2011,
in
preparation).
In
terms
of
geographic
location,
this
area
is
part
of
western
Yunnan
Province,
China,
yet
in
a
tectonic
context,
the
area
is
within
the
Shan
Thai
Block
near
the
eastern
syntaxis
of
the
India–Eurasia
collision
belt
(
Fig.
1);
where
locally
intense
internal
deformation,
involving
fold-
ing
and
faulting
of
thick
upper
Paleozoic
through
lower
Tertiary
strata
occurred
in
response
to
the
India–Eurasia
collision
and
dis-
placement
of
components
of
southeast
Asia
(Wang
and
Burchfiel,
1997
).
A
range
of
paleomagnetic
results
have
been
obtained
from
Cretaceous
to
Eocene
red
bed
strata
from
different
localities
in
this
broad
region,
reflecting
a
heterogeneous
deformation
field.
Inferred
clockwise
rotations
of
local
regions
within
the
Lanping
Simao
belt
are
as
large
as
100
◦
,
and
estimates
of
southward
lat-
itudinal
displacement
relative
to
both
the
Eurasia
and
the
South
China
reference
frames
range
from
insignificant
to,
more
typically,
about
10
◦
and
no
greater
than
12
◦
(Table
5,
Figs.
5
and
6).
The
areas
that
are
interpreted
to
have
experienced
large
magnitudes
of
rotation
likely
reflect
local
deformation
of
upper-crustal
elements
during
differential
crustal
shortening
(MacDonald,
1980;
Burchfiel
et
al.,
2007).
In
some
areas
of
the
belt,
such
as
near
Lanping
and
Mengla,
somewhat
larger
magnitudes
of
clockwise
rotation
are
suggested
by
data
from
Eocene
red
beds,
although
lesser
clock-
wise
rotations
have
been
estimated
based
on
data
from
underlying
Upper
Cretaceous
red
beds
(Fig.
5).
Similar,
seemingly
conflicting
results
have
been
obtained
for
inferred
latitudinal
displacements,
with
younger,
overlying
redbeds
yielding
larger
values
than
older
rocks
(Fig.
6).
It
is
possible
that
these
data
sets
may
imply
the
complexity
of
local
tectonic
displacements.
Alternative
interpreta-
tions
involve
the
overall
reliability
of
the
age
interpretation
of
the
rocks
and,
more
importantly,
the
age
of
their
characteristic
mag-
netization.
It
is
often
difficult
to
determine
a
sufficiently
accurate
age
of
thick
sequences
of
medium
to
coarse
grained
continental
red
beds
because
fossils
are
uncommon.
Age
assignments
for
red
bed
sequences
are
often
based
on
stratigraphic
correlations,
and,
together
with
inaccuracies
in
interpreting
the
ages
of
magneti-
zations
characteristic
of
the
rocks,
these
can
result
in
inaccurate
tectonic
interpretations
of
paleomagnetic
data,
leading
to
unrea-
sonable
conclusions,
especially
in
strongly
deformed
rocks,
like
parts
of
Southeast
Asia.
Paleomagnetic
data
from
Upper
Jurassic
to
Cretaceous
conti-
nental
red
beds,
exposed
near
the
western
margin
of
the
Shan
Thai
Block
near
the
Sagaing
right-lateral
strike-slip
fault
(Fig.
1),
show
that
the
study
area
was
rotated
in
a
clockwise
sense
by
nearly
30
◦
(29.1
±
5.2
◦
)
and
may
have
been
translated
north-
ward
by
about
8
◦
(7.8
±
4.0
◦
)
(Richter
and
Fuller,
1996)
(Table
3,
Figs.
4
and
5).
A
component
of
the
inferred
deformation
of
this
area
is
likely
a
consequence
of
dextral
displacement
along
the
more
than
1000
km
long
Sagaing
fault
system,
that
formed
and
during
the
India–Eurasia
collision
process
and
remains
very
active
(Vigny
et
al.,
2003;
Tsutsumi
and
Sato,
2009).
Under
those
circumstances
where
there
is
ample
evidence
of
sufficient
averaging
of
the
geo-
magnetic
field
and
that
data
can
be
accurately
referenced
to
the
paleohorizontal,
paleomagnetic
data
can
provide
a
powerful
means
of
quantifying
important
components
of
the
deformation
matrix,
specifically
vertical
axis
rotation
and
latitudinal
components
of
displacement.
Paleomagnetic
data
based
on
studies
that
have
con-
centrated
or
targeted
sampling
in
tectonically
active
areas
must
be
interpreted
with
caution,
as
they
represent
the
cumulative
sum
of
all
components
of
deformation
experienced
by
the
rocks
studied
and
thus
may
not
be
an
accurate
representation
of
the
phase
of
deformation
of
interest
(e.g.,
over
a
specific
time
interval).
Rarely
is
it
the
case
that
a
single
set
of
observations
from
a
relatively
restricted
locality
an
accurate
reflection
of
the
coherent
motion
of
the
entire
lithospheric
block.
Caution
should
be
taken
in
the
interpretation
of
paleomagnetically
defined
rotations
and/or
trans-
lations
of
specific
areas,
in
particular
in
the
context
of
the
motion
of
features
that
encompass
a
considerably
larger
area
than
that
examined
in
the
paleomagnetic
study.
5.
Conclusions
In
the
context
of
the
history
of
late
Mesozoic
to
present
defor-
mation
of
Vietnam
and
immediately
adjacent
areas,
overall,
the
paleomagnetic
data
from
Cretaceous
and
Paleogene
sedimentary
rocks
from
the
South
China
Block
and
Indochina
regions
can
be
interpreted
to
indicate
that
the
South
China
Block
has
been
rela-
tively
stable
with
respect
to
the
Eurasian
continent
at
least
since
the
Cretaceous.
Components
of
vertical
axis
rotation
and
latitudinal
translation,
dominantly
in
a
south-directed
sense,
have
contributed
to
the
deformation
of
crustal
to
lithosphere
scale
elements
of
South-
east
Asia.
We
suspect
that
results
from
some
localities
reflect
more
localized
deformation
of
elements
confined
to
the
upper
crust,
rather
than
involving
an
entire
lithosphere
section.
The
India–Eurasia
collision
strongly
deformed
the
Indochina–Shan
Thai
Block,
in
particular
in
the
areas
near
the
collision
belt.
During
the
Cenozoic,
Indochina
and
parts
of
Sundaland
experienced
complex
internal
deformation
and
clearly
did
not
behave
as
a
coherent
block,
as
suggested
by
extrusion
models.
The
Red
River
fault
system,
which
is
juxtaposed
on
or
adjacent
to
the
long-lived
left
lateral
Ailao
Shan
shear
zone,
may
not
entirely
demarcate
the
South
China
Block
and
the
Indochina
Block.
Some
of
the
available
paleomagnetic
data
are
interpreted
to
suggest
that
at
least
some
terranes
located
southwest
of
the
fault
system
have
not
been
significantly
rotated
nor
translated
southward
relative
to
the
South
China
block
since
the
Cretaceous.
However,
the
preponderance
of
paleomagnetic
results
from
much
of
the
Lanping
Simao
belt
in
western
Yunnan
Province,
China,
in
consistent
with
a
modest
amount
of
southward
displace-
ment,
and
variable
clockwise
rotation,
with
the
observed
range
in
rotation
magnitudes
possibly
reflecting
more
localized
deforma-
tion
unrelated
to
that
affecting
the
remainder
of
the
lithosphere
in
this
region.
A
mobile,
more
lithosphere
scale
boundary
between
the
South
China
and
Indochina
blocks
in
the
extrusion
model
is
possibly
located,
at
the
latitude
of
northwest
Vietnam,
southwest
of
the
Red
River
fault.
Although
the
data
upon
which
this
is
based
are
very
sparse,
the
inferred
very
modest
southward
displacement
of
the
southern
part
of
Vietnam
may
be
consistent
with
the
extru-
sion
model,
however,
no
clockwise
rotation
has
been
observed
from
this
area.
Modest
magnitude
counterclockwise
rotations
appear
to
characterize
the
Borneo
and
Malaya
peninsula
areas,
located
farther
to
the
south
(Fuller
et
al.,
1991),
indicating
that
the
complex
tec-
tonic
evolution
of
the
Southeast
Asian
region
cannot
be
completely
explained
by
any
single,
simple
tectonic
model.
Acknowledgements
The
research
has
been
supported
by
a
grant
for
the
basic
research
project
(No.
105.03.05.09)
from
National
Foundation
for
Science
and
Technology
Development
(Nafosted)
of
Vietnam
to
Cung
Thuong
Chi.
In
addition,
Geissman
acknowledges
sup-
port
from
National
Science
Foundation
awards
EAR9706300
and
EAR0537604.
Mr.
Scott
Muggleton
assisted
Geissman
with
field
sampling
in
northern
Vietnam;
and
the
collaboration
with
Dr.
N.V.
Pho
over
this
time
period
is
greatly
appreciated.
We
wish
to
thank
Dr.
Mike
Fuller
for
helpful
comments
on
the
manuscript.
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
10 T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx
References
Besse,
J.,
Courtillot,
V.,
1991.
Revised
and
synthetic
apparent
polar
wander
paths
of
the
African,
Eurasian,
North
America
and
Indian
Plates,
and
true
polar
wander
since
200
Ma.
Journal
of
Geophysical
Research
B96,
4029–4050.
Besse,
J.,
Courtillot,
V.,
2002.
Apparent
and
true
polar
wander
and
the
geometry
of
the
geomagnetic
field
over
the
last
200
Myr
–
art.
no.
2300.
Journal
of
Geophysical
Research-Solid
Earth
107
(B11),
2300.
Bilardello,
D.,
Kodama,
K.P.,
2009.
Measuring
remanence
anisotropy
of
hematite
in
red
beds:
anisotropy
of
high
field
isothermal
remanence
magnetization
(hf-AIR).
Geophysical
Journal
International
178,
1260–1273.
Bilardello,
D.,
Kodama,
K.P.,
2010.
Rock
magnetic
evidence
for
inclination
shallowing
in
the
early
Carboniferous
Deer
Lake
Group
red
beds
of
western
Newfoundland.
Geophysical
Journal
International
181,
275–289.
Burchfiel,
B.C.,
Studnicki-Gizbert,
C.,
Geissman,
J.W.,
Wang,
E.,
Lianzhong,
C.,
2007.
How
much
strain
can
continental
crust
accommodate
without
developing
obvious,
through-going
faults?
In:
Whence
the
Mountains?
Inquiries
into
the
Evolution
of
Orogenic
Systems:
A
Volume
in
Honor
of
Raymond
A.
Price.
Geolog-
ical
Society
of
America
Special
Paper
433.
Geological
Society
of
America,
Boulder,
pp.
51–62.
Butler,
R.,
1992.
Paleomagnetism.
Blackwell
Scientific
Publications,
Boston,
USA.
Chan,
L.S.,
1991.
Paleomagnetism
of
late
Mesozoic
granitic
intrusions
in
Hong
Kong:
implications
for
Upper
Cretaceous
reference
pole
of
South
China.
Journal
of
Geophysical
Research
96B,
327–335.
Chen,
H.,
Dobson,
J.,
Heller,
F.,
Hao,
J.,
1995.
Paleomagnetic
evidence
for
clockwise
rotation
of
the
Simao
region
since
the
Cretaceous:
a
consequence
of
India–Asia
collision.
Earth
and
Planetary
Science
Letters
134,
203–217.
Chen,
Y.,
Courtillot,
V.,
Cogne,
J.P.,
Besse,
J.,
Yang,
Z.,
Enkin,
R.J.,
1993.
The
configura-
tion
of
Asia
prior
to
the
collision
of
India:
Cretaceous
paleomagnetic
constraints.
Journal
of
Geophysical
Research
B98,
21927–21941.
Chi,
C.T.,
Dorobek,
S.L.,
2004.
Cretaceous
palaeomagnetism
of
Indochina
and
sur-
rounding
regions:
Cenozoic
tectonic
implications.
In:
Malpas,
J.,
Fletcher,
C.J.N.,
Ali,
J.R.,
Aitchison,
J.C.
(Eds.),
Aspects
of
the
Tectonic
Evolution
of
China,
vol.
226.
Geological
Society,
London,
Special
Publication.
Chi,
C.T.,
2001.
Results
of
paleomagnetic
study
on
Jurassic
sandstone
and
siltstone
of
the
Ha
Coi
formation
and
their
tectonic
implications.
Journal
of
Geology,
Series
B
17–18,
35–44.
Chi,
C.T.,
Yem,
N.T.,
Cuong,
N.Q.,
2000.
Paleomagnetic
results
of
Late
Jurassic–Cretaceous
extrusive
and
intrusive
rocks
from
northwestern
region
of
Vietnam.
Journal
of
Geology,
Series
A
256
(1–2),
1–8
(in
Vietnamese).
Chi,
C.T.,
Cuong,
N.Q.,
Yem,
N.T.,
1999.
Paleomagnetic
results
of
Cretaceous
rock
for-
mations
from
South-east
Asia
region
and
from
South
China
block:
their
tectonic
implications.
Journal
of
Geology,
Series
A
252
(5–6),
8–17
(in
Vietnamese).
Chi,
C.T.,
Yem,
N.T.,
Bao,
N.X.,
1998.
Paleomagnetic
study
of
Late
Jurassic-Cretaceous
extrusive
and
intrusive
igneous
rocks
from
South
Vietnam:
tectonic
implications
for
the
Cenozoic
tectonic
history
of
Indochina
Block.
Journal
of
Geology,
Series
A
249
(11–12),
1–8
(in
Vietnamese).
Chi,
C.T.,
1996.
Paleomagnetism
of
Mesozoic
and
Cenozoic
rocks
from
Vietnam:
implications
for
the
Tertiary
tectonic
history
of
Indochina
and
a
test
of
the
extrusion
model.
PhD
Thesis.
Texas
A&M
University,
College
Station,
Texas.
Dewey,
J.F.,
Cande,
S.,
Pitman
III,
W.C.,
1989.
Tectonic
evolution
of
the
India/Eurasia
collision
zone.
Eclogae
Geologicae
Helvetiae
82,
717–734.
Donohoo-Hurley,
L.L.,
2011.
Magnetic
records
from
uppermost
Triassic
to
earliest
Jurassic
Red
Beds,
Utah
and
Arizona,
and
from
mid-Pleistocene
lake
beds,
New
Mexico.
Earth
and
Planetary
Sciences.
Albuquerque,
University
of
New
Mexico.
PhD,
p.
149.
Donohoo-Hurley,
L.L.,
Geissman,
J.W.,
Wawrzyniec,
T.F.,
Roy,
M.,
Inclination
bias
of
the
uppermost
Triassic
to
lowermost
Jurassic
Moenave
Formation,
Utah
and
Ari-
zona:
how
can
time-equivalent
data
from
the
American
Southwest
be
reconciled
with
those
from
eastern
North
America?
in
preparation.
England,
P.C.,
Houseman,
G.A.,
1989.
Extension
during
continental
convergence,
with
application
to
the
Tibetan
Plateau.
Journal
of
Geophysical
Research
94B,
17561–17579.
England,
P.C.,
Molnar,
P.,
1990.
Right
lateral
shear
and
rotation
as
the
explanation
for
strike-slip
faulting
in
eastern
Tibet.
Nature
344,
140–142.
Enkin,
R.J.,
Chen,
Y.,
Courtillot,
V.,
Besse,
J.,
Xing,
I.,
Zhang,
Z.,
Zhuang,
Z.,
Zhang,
J.,
1991a.
A
Cretaceous
pole
from
South
China
and
the
Mesozoic
hairpin
turn
of
the
Eurasian
apparent
polar
wander
path.
Journal
of
Geophysical
Research
96B,
4007–4027.
Enkin,
R.J.,
Courtillot,
V.,
Xing,
I.,
Zhang,
Z.,
Zhuang,
Z.,
1991b.
The
stationary
Cretaceous
paleomagnetic
pole
of
Sichuan
(South
China
Block).
Tectonics
10,
547–559.
Enkin,
R.J.,
Yang,
Z.,
Chen,
Y.,
Courtillot,
V.,
1992.
Paleomagnetic
constraints
on
the
geodynamic
history
of
the
major
blocks
of
China
from
the
Permian
to
the
present.
Journal
of
Geophysical
Research
B97,
13953–13989.
Fuller,
M.,
Haston,
R.,
Lin,
J.,
Richter,
B.,
Schmidtke,
E.,
Almasco,
J.,
1991.
Tertiary
paleomagnetism
of
regions
around
the
South
China
Sea.
Journal
of
Southeast
Asian
Earth
Sciences
6,
161–184.
Funahara,
S.,
Nishiwaki,
N.,
Miki,
M.,
Murata,
F.,
Otofuji,
Y-I.,
Wang,
Y.Z.,
1992.
Paleo-
magnetic
study
of
Cretaceous
rocks
from
the
Yangtze
block,
central
Yunnan,
China:
implications
for
the
India–Asia
collision.
Earth
and
Planetary
Science
Letters
113,
77–91.
Funahara,
S.,
Nishiwaki,
N.,
Miki,
M.,
Murat,
F.,
Otofuji,
Y-I.,
Wang,
Y.Z.,
1993.
Clock-
wise
rotation
of
the
Red
River
fault
inferred
from
paleomagnetic
study
of
Cretaceous
rocks
in
the
Shan-Thai-Malay
block
of
western
Yunnan,
China.
Earth
and
Planetary
Science
Letters
117,
29–42.
Gilder,
S.,
Coe,
R.,
Wu,
H.,
Kuang,
G.,
Zhao,
X.,
Wu,
Q.,
Tang,
X.,
1993.
Cretaceous
and
Tertiary
paleomagnetic
results
from
southeast-China
and
their
tectonic
implications.
Earth
and
Planetary
Science
Letters
117,
637–652.
Gilder,
S.A.,
Gill,
J.,
Coe,
R.S.,
Zhao,
X.,
Liu,
Z.,
Wang,
G.,
Yuan,
K.,
Liu,
W.,
Kuang,
G.,
Wu,
H.,
1996.
Isotopic
and
paleomagnetic
constraints
on
the
Mesozoic
tectonic
evo-
lution
of
South
China.
Journal
of
Geophysical
Research
101
(B7),
16137–16154.
Gilder,
S.A.,
LeLoup,
P.H.,
Courtillot,
V.,
Chen,
Y.,
Coe,
R.,
Zhao,
X.X.,
Xiao,
W.J.,
Halim,
N.,
Cogne,
J.P.,
Zhu,
R.,
1999.
Tectonic
evolution
of
the
Tancheng-Lujiang
(Tan-
Lu)
Fault
via
Middle
Triassic
to
Early
Cenozoic
paleomagnetic
data.
Journal
of
Geophysical
Research
104
(15),
365–375.
Gillett,
S.L.,
Geissman,
J.W.,
1993.
Regional
late
Paleozoic
remagnetization
of
shallow-water
carbonate
rocks
in
the
Great
Basin:
the
usefulness
of
micro-fold
tests
from
late
compaction
fabrics.
In:
Applications
of
Paleomag-
netism
to
Sedimentary
Geology.
SEPM
(Society
for
Sedimentary
Geology),
pp.
129–147.
Hankard,
F.,
Cogne,
J P.,
Kravchinsky,
V.,
2005.
A
new
Late
Cretaceous
paleomagnetic
pole
for
the
west
of
Amuria
block
(Khurmen
Uul,
Mongolia).
Earth
and
Planetary
Science
Letters
236,
359–373.
Hu,
L.,
Li,
P.,
Ma,
X.,
1990.
A
magnetostratigraphic
study
of
Cretaceous
redbeds
from
Shanghan,
western
Fujian,
China
(in
Chinese).
Geology
of
Fujian
1,
33–42.
Huang,
K.,
Opdyke,
N.D.,
1992a.
Paleomagnetism
of
Cretaceous
to
lower
Tertiary
rocks
from
southwestern
Sichuan:
a
revisit.
Earth
and
Planetary
Science
Letters
112,
29–40.
Huang,
K.,
Opdyke,
N.D.,
1993.
Paleomagnetic
results
from
Cretaceous
and
Jurassic
rocks
of
south
and
southwest
Yunnan:
evidence
for
large
clockwise
rotation
in
the
Indochina
and
Shan-Thai-Malay
terranes.
Earth
and
Planetary
Science
Letters
117,
507–524.
Hsu,
V.,
1987.
Paleomagnetic
results
from
one
of
the
red
basins
in
South
China.
EOS
Trans.
AGU
68,
295.
Hsu,
K.J.,
Shuh,
S.,
Li,
J.,
Chen,
H.,
Pen,
H.,
Sengor,
A.M.C.,
1988.
Mesozoic
overthrust
tectonics
in
south
China.
Geology
16,
418–421.
Jackson,
J.,
Molnar,
P.,
1990.
Active
faulting
and
block
rotation
in
the
west-
ern
Transverse
Ranges,
California.
Journal
of
Geophysical
Research
95
(B13),
22073–22078.
Kent,
D.V.,
Xu,
G.,
Huang,
K.,
Zhang,
W.Y.,
Opdyke,
N.D.,
1986.
Paleomagnetism
of
Upper
Cretaceous
rocks
from
South
China.
Earth
and
Planetary
Science
Letters
79,
179–184.
Kent,
D.V.,
Olsen,
P.E.,
2008.
Early
Jurassic
magnetostratigraphy
and
paleolati-
tudes
from
the
Hartford
continental
rift
basin
(eastern
North
America):
testing
for
polarity
bias
and
abrupt
polar
wander
in
association
with
the
Central
Atlantic
magmatic
province.
Journal
of
Geophysical
Research
113,
B06105,
doi:06110.01029/02007JB005407.
Leloup,
P.,
Arnaud,
N.,
Lacassin,
R.,
Kienast,
J.,
Harrison,
T.,
Trong,
T.,
Replumaz,
A.,
Tapponnier,
P.,
2001.
New
constraints
on
the
structure,
thermochronology,
and
timing
of
the
Ailao
Shan-Red
River
shear
zone,
SE
Asia.
Journal
of
Geophysical
Research
106
(B4),
6683–6732.
Li,
Z.,
Metcalfe,
I.,
Wang,
X.F.,
1995.
Vertical-axis
block
rotation
in
southeast
China:
new
paleomagnetic
results
from
Hainan
Island.
Geophysical
Research
Letters
22,
3071–3074.
Lin,
J.,
1984.
The
apparent
polar
wander
paths
for
the
North
and
South
China
blocks.
PhD
Thesis.
University
of
California,
Santa
Barbara.
Lowrie,
W.,
Hirt,
A.,
Kligfield,
R.,
1986.
Effects
of
tectonic
deformation
on
the
rema-
nent
magnetization
of
rocks.
Tectonics
5,
713–722.
MacDonald,
W.D.,
1980.
Net
tectonic
rotation,
apparent
tectonic
rotation,
and
the
structural
tilt
correction
in
paleomagnetic
studies.
Journal
of
Geophysical
Research
B85,
3659–3669.
McCabe,
C.,
Elmore,
R.D.,
1989.
The
occurrence
and
origin
of
late
Paleozoic
remag-
netization
in
the
sedimentary
rocks
of
North
America.
Review
of
Geophysics
27,
471–494.
Minyuk,
P.S.,
Stone,
D.B.,
2009.
Paleomagnetic
determination
of
paleolatitude
and
rotation
of
Bering
Islands
(Komandorsky
Islands)
Russia:
comparison
with
rotations
in
the
Aleutian
Islands
and
Kamtchatka.
Stephan
Mueller
Special
Pub-
lication
Series
4,
329–348.
Otofuji,
Y-I.,
Inoue,
Y.,
Funahara,
S.,
Murata,
F.,
Zheng,
X.,
1990.
Paleomagnetic
study
of
eastern
Tibet
–
deformation
of
the
Three
Rivers
region.
Geophysical
Journal
International
103,
85–94.
Otofuji,
Y-I.,
Liu,
Y.,
Yokoyama,
M.,
Tamai,
M.,
Yin,
J.,
1998.
Tectonic
deformation
of
the
southwestern
part
of
the
Yangtze
craton
inferred
from
paleomagnetism.
Earth
and
Planetary
Science
Letters
156,
47–60.
Pares,
J.M.,
Van
der
Pluijm,
B.A.,
Dinares-Turell,
J.,
1999.
Evolution
of
magnetic
fabrics
during
incipient
deformation
of
mudrocks
(Pyrenees,
northern
Spain).
Tectono-
physics
307,
1–14.
Peltzer,
G.,
Tapponnier,
P.,
1988.
Formation
and
evolution
of
strike-slip
faults,
rifts,
and
basins
during
the
India–Asia
collision:
an
experimental
approach.
Journal
of
Geophysical
Research
93B,
15085–15117.
Pueyo,
E.L.,
Pocovi,
A.,
Millan,
H.,
Sussman,
A.J.,
2004.
Map-view
models
for
cor-
recting
and
and
calculating
shortening
estimates
in
rotated
thrust
faults
using
paleomagnetic
data.
Boulder,
Geological
Society
of
America.
Special
Paper
383,
57–71.
Replumaz,
A.,
Tapponnier,
P.,
2003.
Reconstruction
of
the
deformed
collision
zone
between
India
and
Asia
by
backward
motion
of
lithosphere
blocks.
Journal
of
Geophysical
Research
108,
doi:10.1029/2001JB000661.
Richter,
B.,
Fuller,
M.,
1996.
Palaeomagnetism
of
the
Sibumasu
and
Indochina
blocks:
Implications
for
the
extrusion
tectonic
model.
In:
Hall,
R.,
Blundell,
D.
(Eds.),
Tec-
tonic
Evolution
of
Southeast
Asia,
vol.
106.
Geological
Society,
London,
Special
Publication,
pp.
203–224.
Please
cite
this
article
in
press
as:
Cung,
T.C.,
Geissman,
J.W.,
A
review
of
the
paleomagnetic
data
from
Cretaceous
to
lower
Tertiary
rocks
from
Vietnam,
Indochina
and
South
China,
and
their
implications
for
Cenozoic
tectonism
in
Vietnam
and
adjacent
areas.
J.
Geodyn.
(2013),
doi:
10.1016/j.jog.2011.11.008
ARTICLE IN PRESS
G
Model
GEOD-1103;
No.
of
Pages
11
T.C.
Cung,
J.W.
Geissman
/
Journal
of
Geodynamics
xxx (2013) xxx–
xxx 11
Ron,
H.,
Freund,
R.,
Garfunkel,
Z.,
Nur,
A.,
1984.
Block
rotation
by
strike-slip
faul-
ting.
Structural
and
paleomagnetic
evidence.
Journal
of
Geophysical
Research
89,
6256–6270.
Roperch,
P.,
Fornari,
M.,
Herail,
G.,
Parraguez,
G.,
2000.
Tectonic
rotations
within
the
Bolivian
Altiplano:
Implications
for
the
geodynamic
evolution
of
the
central
Andes
during
the
Late
Tertiary.
Journal
of
Geophysical
Research
105,
795–820.
Sato,
K.,
Liu,
Y.,
Zhu,
Z.,
Yang,
Z.,
Otofuji,
Y I.,
1999.
Paleomagnetic
study
of
middle
Cretaceous
rocks
from
Yunlong,
western
Yunnan,
China:
evidence
of
southward
displacement
of
Indochina.
Earth
and
Planetary
Science
Letters
165,
1–15.
Sato,
K.,
Liu,
Y.,
Zhu,
Z.,
Yang,
Z.,
Otofuji,
Y I.,
2001.
Tertiary
paleomagnetic
data
from
northwestern
Yunnan,
China:
further
evidence
for
large
clockwise
rotation
of
the
Indochina
block
and
its
tectonic
implications.
Earth
and
Planetary
Science
Letters
185,
185–198.
Stamatakos,
J.,
Hirt,
A.,
1994.
Palaeomagnetic
considerations
of
the
development
of
the
Pennsylvania
Salient
in
the
central
Appalachians.
Tectonophysics
231
(4),
237–255.
Sun,
Z.,
Yang,
Z.,
Yang,
T.,
Pei,
J.,
Yu,
Q.,
2006.
New
Late
Cretaceous
and
Paleogene
pale-
omagnetic
results
from
South
China
and
their
Geodynamic
implications.
Journal
of
Geophysical
Research
111,
B03101,
doi:03110.01029/02004JB003455.
Sussman,
A.J.,
Butler,
R.F.,
Dinares-Turell,
J.,
Verges,
J.,
2004.
Vertical
axis
rotation
of
a
foreland
fold
and
implications
for
orogenic
curvature:
and
example
from
the
Southern
Pyrenees,
Spain.
Earth
and
Planetary
Science
Letters
218,
435–449.
Takemoto,
K.,
Halim,
N.,
Otofuji,
Y I.,
Tran,
V.T.,
Le,
V.D.,
Hada,
S.,
2005.
New
paleo-
magnetic
constraints
on
the
extrusion
of
Indochina:
Late
Cretaceous
results
from
the
Song
Da
terrane,
northern
Vietnam.
Earth
and
Planetary
Science
Letters
229,
273–285.
Tapponnier,
P.,
Peltzer,
G.,
Le
Dain,
A.Y.,
Armijo,
R.,
1982.
Propagating
extrusion
tectonics
in
Asia:
new
insights
from
simple
experiments
with
plasticine.
Geology
10,
611–616.
Tapponnier,
P.,
Peltzer,
G.,
Armijo,
R.,
1986.
On
the
mechanism
of
the
collision
between
India
and
Asia.
In:
Coward,
M.P.,
Ries,
A.C.
(Eds.),
Collision
Tectonics,
vol.
19.
Geological
Society,
London,
Special
Publication,
pp.
115–157.
Tauxe,
L.,
Kent,
D.V.,
2004.
A
simplified
statistical
model
for
the
geomagnetic
field
and
the
detection
of
shallow
bias
in
paleomagnetic
inclinations:
was
the
ancient
magnetic
field
dipolar?
In:
Channell,
J.E.T.
(Ed.),
Timescales
of
the
Paleomagnetic
Field,
vol.
145.
American
Geophysical
Union,
Washington,
DC,
pp.
101–116.
Taylor,
B.,
Hayes,
D.E.,
1980.
The
tectonic
evolution
of
the
South
China
Basin.
In:
Hayes,
D.E.
(Ed.),
The
Tectonic
and
Geologic
Evolution
of
Southeast
Asian
Seas
and
Islands.
Part
1.
Geophysical
Monograph
Series,
vol.
23.
AGU,
Washington,
DC,
pp.
89–104.
Taylor,
B.,
Hayes,
D.E.,
1983.
Origin
and
history
of
the
South
China
Sea
Basin.
In:
Hayes,
D.E.
(Ed.),
The
Tectonic
and
Geologic
Evolution
of
Southeast
Asian
Seas
and
Islands.
Part
2.
Geophysical
Monograph
Series,
vol.
27.
AGU,
Washington,
DC,
p.
23-56.
Tsuneki,
Y.,
Morinaga,
H.,
Liu,
Y.,
2009.
New
palaeomagnetic
data
supporting
the
extent
of
the
stable
body
of
the
South
China
Block
since
the
Cretaceous
and
some
implications
on
magnetization
acquisition
of
red
beds.
Geophysical
Journal
International
178,
1327–1336.
Tsutsumi,
H.,
Sato,
H.,
1930.
Tectonic
geomorphology
of
the
southernmost
Sagaing
Fault
and
surface
rupture
associated
with
the
May,
1930,
Pego
(Bago)
earthquake,
Myanmar.
Bulletin
of
the
Seismological
Society
of
America
99,
2155–2168.
Van
der
Voo,
R.,
1993.
Paleomagnetism
of
the
Atlantic,
Tethys,
and
Iapetus
Oceans,
First
ed.
Cambridge
University
Press,
Cambridge,
411
pp.
Van
der
Voo,
R.,
Torsvik,
T.H.,
2011.
The
history
of
remagnetization
of
sedimentary
rocks:
descriptions,
developments,
discoveries.
In:
Elmore,
R.D.
(Ed.),
Remag-
netization
and
Chemical
Alteration
of
Sedimentary
Rocks.
Geological
Society
of
London,
London.
Vigny,
C.,
Socquet,
A.,
Rangin,
C.,
Chamot-Rooke,
N.,
Pubellier,
M.,
Bouin,
M
N.,
Bertrand,
G.,
Becker,
M.,
2003.
Present
day
crustal
deformation
around
Sagaing
Fault,
Myanmar.
Journal
of
Geophysical
Research
108
(B11),
2533,
doi:10.1029/2002JB001999.
Wang,
E.,
Burchfiel,
B.C.,
1997.
Interpretation
of
Cenozoic
Tectonics
in
the
right-lateral
accommodation
zone
between
the
Ailao
Shan
shear
zone
and
the
eastern
Himalayan
syntaxis.
International
Geology
Review
39,
191–219.
Xu,
J.W.,
1993.
Basic
characteristics
and
tectonic
evolution
of
the
Tancheng-Lujiang
fault
zone.
In:
Xu,
J.W.
(Ed.),
The
Tancheng-Lujiang
Wrench
Fault
System.
John
Wiley,
New
York,
pp.
1–49.
Yang,
Z.,
Besse,
J.,
1993.
Paleomagnetic
study
of
Permian
and
Mesozoic
sedimentary
rocks
from
Northern
Thailand
supports
the
extrusion
model
for
Indochina.
Earth
and
Planetary
Science
Letters
117,
525–552.
Yang,
Z.,
Yih,
J.,
Sun,
Z.,
Otofuji,
Y I.,
Sato,
K.,
2001.
Discrepant
Cretaceous
paleo-
magnetic
poles
between
Eastern
China
and
Indochina:
a
consequence
of
the
extrusion
of
Indochina.
Tectonophysics
334,
101–113.
Yoshioka,
S.,
Liu,
Y.Y.,
Sato,
K.,
Inokuchi,
H.,
Su,
L.,
Zaman,
H.,
Otofuji,
Y I.,
2003.
Paleomagnetic
evidence
for
post-Cretaceous
internal
deformation
of
the
Chuan
Dian
Fragment
in
the
Yangtze
block:
a
consequence
of
indentation
of
India
into
Asia.
Tectonophysics
376,
61–74.
Zhai,
Y.,
Seguin,
M.K.,
Zhou,
Y.,
Dong,
J.,
Zheng,
Y.,
1992.
New
paleomagnetic
data
from
the
Huanan
block,
China,
and
Cretaceous
tectonics
in
eastern
China.
Physics
of
the
Earth
and
Planetary
interiors
73,
163–188.
Zhu,
Z.,
Hao,
T.,
Zhao,
H.,
1988.
Paleomagnetic
study
on
the
tectonic
motion
of
Pan-xi
block
and
adjacent
area
during
Yin
Zhi-Yan
Shan
period.
Acta
Geophysica
Sinica
31,
420–431
(in
Chinese).
Zhu,
Z.,
Morinaga,
H.,
Gui,
R.,
Xu,
S.,
Liu,
Y.,
2006.
Paleomagnetic
constraints
on
the
extent
of
the
stable
body
of
the
South
China
Block
since
the
Cretaceous:
new
data
from
the
Yuanma
Basin,
China.
Earth
and
Planetary
Science
Letters
248,
533–544.
Zijderveld,
J.D.A.,
1967.
A.C.
Demagnetization
of
rocks:
analysis
of
results.
In:
Collinson,
D.W.,
Creer,
K.M.,
Runcorn,
S.K.
(Eds.),
Methods
in
Palaeomagnetism.
Elsevier,
Amsterdam,
pp.
254,
286.
