Dipolar Intermolecular Interactions, Structural Development, and

Journal of Applied Mechanics Vol.3, pp.585-594 Viscous-Plastic

Analysis

(August 2000)

of Crustal

JSCE

Deformation

of Fault-bend

Folds

摺曲 断層 を有 す る地殻変形 の粘塑性解析 に関す る研 究

Yun

GAO*

高昀

Zhishen

呉

WU**

Yutaka

智深 村上

*Student Member of JSCE,Dr.Cand.,Dept.of

MURAKAMI

***

裕

Urban & Civil Eng.Ibaraki University

(4-12-4,Nakanarusawa,Hitachi,316-8511,[email protected]) Member**of JSCE,Dr.Eng.,Asso.Prof.,Dept.of Urban & Civil Eng.Ibaraki University (4-12-4,Nakanarusawa,Hitachi,316-8511,[email protected]) Member of JSCE,Dr.Eng.,Chief *** of Geophysical Analysis Section,Geophysics Department,Geological Survey of Japan (1-1-3,Higashi,Tsukuba,Ibaraki

305-0046,[email protected])

In this paper,a finite element model is formulated to simulate the crustal of deformation of faultbend folding with the large scale features using the large deformation theory in which the fault surface is represented with the master-slave method.The viscous-plastic material properties modeled by the Perzyna viscoplasticity theory are used to simulate the pressure solution creep and cataclasis respectively.Moreover,an interfacial viscous-plastic model is adopted to represent the nonlinear behavior of the fault surface.Effects on different structural models and parameters of fault-bend folds are simulated.Contours and development of the stress invariant,horizontal strain, equivalent viscous plastic strain by following an individual particle and traction on the fault surface are shown.The numerical results comparing with kinematic models are also discussed in order to infer a sequence of the deformation mechanisms. Key Words:fault-bend folding,master-slave method,viscous plastic,crustal

1

INTRODUCTION

creep and cataclasis of fault-bend

The nature and history of rock deformation during movement over thrust-fault ramps have been investigated using kinematic and mechanical models as well as field observations1) 2) 3).Kinematic models of fault-bend folding assume flexural-slip or flexural-flow folding during movement over a rigid footwall in order to simulate the development of a hanging-wall anticline 5) Because layer thickness is constant in most of these kinematic models,there is layer-parallel slip or layerparallel shear strain but no layer-parallel shortening or extension.Analytical and numerical models have been also used to simulate deformation around a ramp.Berger & Johnson (1980)1) discuss the development of ramp anticline above a rigid footwall using a linear viscous material,with constant friction along the ramp and frictionless flats.They show that fault friction leads to thickening of the hanging wall above the lower ramp hinge and an increase in fold asymmetry.Erickson & Jamison(1995) use viscous and pressure-dependant plastic material properties to model pressure solution

― 585―

elements

deformation

respectively

folds,

where

the

during

are adopted6).Recently,in

general crustal displacement,a

Fig.1 Schematic

principle

drawing

spring

order to simulate

deformation with new finite element

based on the extended

the development

friction-contact

the

fault discontinuous model is developed

of virtual

work in which

of a fault-bend

fold

the large deformation is formulated by using an updated Lagrange description and the fault surface is represented with the master-slave method (Wu 2000).7) In spite of these accomplishments,the investigation of the effects on both geometry sizes of structures and fault material properties are quite insufficient.This paper is concerned with a viscous-plastic finite element model to simulate different structures of fault-bend folding using large deformation,the Perzyna viscoplasticity theory that there is a fault surface with the master-slave method.An interfacial viscous-plastic law is adopted to represent the behavior of the fault surface.

2FINITE

ELEMENT

FAULT

MODEL7)

FORMULATIOIN

Fig.2 viscous-plastic

model

yield condition F and Drucker-Prager viscous-plastic potential QVPare used as expressed as eq.(2) and (3).

AND

(2)

(3)

τ1,τ3is the 1

(1)

the

yielding is

the

first

stress first

and

and

stress

￠ is the

Considering

the

viscoplastic

prescribed and

external internal

displacement s}is

traction

{f0}

traction jump

Lagrange

on stress

a body

{fc0}

force on

force

by

V,

is

internal the

is

friction.

second

can

be

defined

as

rate

I

stress

proposed

stress-strain

by

relation

of

follows:

(4)

y

coefficient.

is

the

fluid

coefficient;cr

If an integral

step.As

a

is

node even though reach yielding to be in elastic

measure

equivalent

of

the

creep

it had being

surface at some status in current

the

viscous-plastic

viscous-plastic strain

s vp is

introduced.

So

relative

surface is

in

boundary

caused

discontinuous vector;{ƒÃ}

field {r0}

of

strain

Qvp>0,the

deformation,the to

angle

stress.σY

i

Perzyna(1966),when

time

subjected

principal

invariant;J2

yielded formerly doesn't time step,it is considered

is

third

nvarlant,

where

body

domain

8)

Consider a structural system in which the reference configuration of a body exhibiting large slipping along the fault surface so that the whole structural system is characterized by two constitutive relations.One is a volumetric constitutive law that relates stress and strain for the continuous body,while another is a cohesive and frictional surface constitute relation between the traction and displacement jumps for the fault. There are two contributions to the internal virtual works:a volumetric contribution and interface contribution.Based on a Lagrange description,therefore, an incremental formulation of the extended principle of virtual work for a body with an internal interface is written as

The

in continuous

(5)

Sc .Here

Lagrange

{ strain

vector.

where

2.1CONSTITUTIVE CONTINUOUS As

shown

equation

EQUATIONS

IN

DOMAIN in Fig.2,a

model

based on a mixed

(6) viscous-plastic

in continuous method

domain

constitutive is formulated

And

in which the Mohr-Coulomb

― 586―

a,K

are the function

of

a,

and 0

(7)

2.2

MASTER-SLAVE

PLASTIC

METHOD

MODEL

ON FAULT

AND

(10)

VISCOUS

To describe

SURFACE

the inelastic

a viscous-plastic

model Faults

behavior

as shown surface

1

Faults Fig.3 master-slave

slide line segment

the contact

between

surface and a segment the nodes

x2,x3

of the master

and x4.On

surface in which global on master

surface

interpolation be

displacement

surface

coordinates

the slave

described

by

is defined

friction

Ni of

the

node

by

x;on

determined.Moreover,the

(13tcon discontinuous

And

the force increment

displacement

relative

displacement

surface

at

On two

kinds

of

(12)

where{•¢ucvp}is

the

referring

to

traction

is

components,i.e.

the

time

function increment

is

the

incremental function

of

Fc,viscous-plastic

viscous-plastic fluid potential

component by

coefficient (VP

rc, and

A t

master

elastic

or

giving

offered

tangent

the

by

elastic

respectively.The

normal

is

which

relative

(13) surface,the

displacement

described

x1

by the viscous-plastic

m.

components,

either

be

step

discontinuous

inelastic of

time

node

caused

to the total force increment.

after slip

increment;{•¢uc}m of

is added

the

yielding displacement

surface as follows

relative

displacement

is

as

(11)

the

completely

of the node x1 can be obtained

{•¢u}

yielding function is considered

the function of yielding stress 0cY and angle of internal

are used, the point x

(8)

where

2

of the master

to the point x,on

position function

segment,can

x1,on

this segment

corresponding

slave surface,whose the

a node

surface

Fig.4 viscous-plastic model on discontinuous interface In this model,the

Consider

of the fault surface,

in Fig.4 is considered.

and

2.3 time integration

characters

component

and iteration

will

discontinuous

(1)stress

stiffness

in continuous

domain

matrix.

(9)

For update Lagrange formulation,in time step m,the Lagrange stresses {s}mis equal to Cauchy stresses {i}m

(14) As relationship elastic

for

elastic

behavior

between displacement{•¢(•¢u)}can

the

along force

the

increment be

fault and expressed

surface,the the

relative

In continuous domain,the

as

Kirchhoff stresses {tk}

({tk}=[J]{2}) obey the following relation

― 587―

(22)

(15)

where

n

is

the

load

Symmetrical the

tensor

composition

and

step

of

rotation

and

k

is

the

formulation the

iteration [•¢r]

Jaumann

In the total

step. of

vector

differential

{•¢t}

tensor

coordinate,it

can be rewritten

as

is

(23)

[•¢rk*]

tensor [n].

where [T] is the coordinates transformation matrix. (16)

On

the

basis

Lagrange

of

stress

the

vector

above {•¢s}

equations,the can

be

written

2.4 FINITE

incremental

ELEMENT

Considering

as

time

iteration,in

the

continuous upon

(17)

FORMULATION

domain finite

integration,large total and

element

incremental

the

which

can

be

to

finite

where

[Dc]

modified the

first

second and

is

elastic

stiffness order order

{•¢fvP}

(2)traction

stiffness

matrix

terms

of

for incremental

terms;{•¢Evp} is the

matrix large

corresponding

on discontinuous

is

strain the

and

[DGt*]

deformation;

viscous

and

as

plastic

(24)

where

is

{•¢e} {•¢n}

the

element

(18)

(19)

the

surface,

respect

{•¢a},the

obtained

of

fault with

variables

and

consist

viscous-plastic

discretization

nodal

formulation

deformation

system

is

is the strain

traction.

surface

On the discontinuous surface,the traction vector {fcL} can be expressed as the following relation where the super script L' refers to local coordinate and the sub script `c' refers to discontinuous surface.

(20)

Therefore,the incremental traction vector {AfcL}can be written as

Here,the

total

incremental

elastic

interfacial

(21)

{•¢PvP}

is

― 588―

stiffness,

geometrical

the

due

virtual

to

is

the

virtual behavior

the

residual

the

nodal

load

behavior

viscous-plastic {‚ä}is

matrix

stiffness

viscous-plastic {•¢PcvP}

stiffness

in nodal

vector.[B]

consists

discontinuous vector

vector

the

the

and surface.

produced

by

domain

strain

the and

produced

discontinuous is

of

stiffness

continuous load

on

[K*]

by

the

surface. matrix

and

[N] is the interpolation function where the subscript 'L' refers to linear component, subscript 'NL' refers to nonlinear component and 'C' refers to discontinuous component.

3

NUMERICAL

properties on the fault surface

SIMULATIONS

Fig.5 shows a finite element mesh of a structural model with fault-bend folds,which is similar with reference [6].Erickson & Jamison investigated the structure using a finite element model with independent viscous,plastic analysis and constant friction material behavior on the fault surface.In this paper,we focus on the effect of the ramp height and the viscous-plastic material behaviors on the fault surface.Each structural model contains 200 6-node isoparametric,quadratic triangle elements.Plane strain is assumed.The initial fault geometry consists of a 1000m long ramp connecting lower and upper flats.A surface pressure of 75 MPa is applied to the top of the model and the right side of the hanging wall,which simulates a 3km overburden.There is zero shear stress along this top surface of the model.A zero displacement boundary condition,Ux=Uy=0,is used along the left (hinterland) side of the footwall,Uy=0 along the base of the model and Ux=0 along the right (foreland) side of the footwall . A displacement of 25 m per 2500 y time step is imposed on the left side of the hanging wall,a velocity (1 cm y-1) that is consistent with estimates of natural thrust sheet motion.The models are run to a maximum displacement of the left side of the model of 2.5km(100 time steps).

Fig.5 initial,undeformed model,showing

Table

Table 2.Material

1.Description

Six sets of structural models are used to simulate different fault-bend folds as shown in Table 1.All materials of the structural models have same density 2500 kg m-3,Young's modulus 3x104 MPa,Poisson's ratio 0.25,yield strength 27 MPa,Stress-strain slope 2300 MPa,viscous-plastic fluid coefficient r=5x10-14s-1, creep coefficient cr=1.On the fault surface,all materials have same normal stiffness Kn=3x1010MN/m,but the tangent stiffness and the viscous-plastic fluid coefficient are chosen as Table 2.In the corresponding figures,the unit of I1 and (J2)1/2is MPa;traction is MN;slip displacement is m;dip of backlimb and forelimb is degree;time increment is 2500 year.

grid for the finite-element boundary

conditions

of the structure

models

Fig.6Contoursof (a)I1(b)(J2)1/2 (c)Exx(d) ~vp after250,000 yearsfor uniformviscous-plasticmodelA3

― 589―

Fig.6 shows the results of the numerical simulations for the Model A3 which contains a hanging wall and footwall with the uniform viscous-plastic material properties.I1 is higher around the foreland of footwall and in the area from above the upper ramp hinge to the upper backstage of hanging wall(Fig.6a).Higher (J2)112 occurs above the upper ramp hinge,although the maximum value above the lower ramp hinge moves up the ramp during the late stage of the model.Maximum values in (J2)112 also develop below the ramp and in the upper forelimb of the hanging wall (Fig. 6b). The strains Fxxare negative in the trailing syncline and right leading syncline where there are horizontal shortenings and the maximum is in the upper late stage.Maximum negative Fxxis observed from above the upper ramp hinge to the upper backstage of hanging wall. Corresponding to this

result,in the hanging wall anticline syncline,the strains Fxx are positive horizontal extensions and decrease backlimb.Maximum positive Exx is

and left leading where there are from the upper observed in the

place where the hanging wall anticline meets in the left leading syncline (Fig. 6c).The highest viscous-plastic strain is found above the upper plat and nearby the upper ramp hinge with an ellipse shape in the hanging wall (Fig.6d). The numerical results for Model B3 which contains a viscous-plastic hanging wall and a rigid footwall are shown in Fig.7.From these figures,I1 is higher in the area from above the upper ramp hinge to the upper backstage of hanging wall,however,the maximum value is larger than Model A3(Fig. 7a).(J2)1/2 is higher in the area above the low and upper ramp hinge.Also,the maximum value is larger than Model A3(Fig. 7b).The strains Fxx are negative in the trailing syncline but the maximum value which is larger than Model A3 is above the ramp.Maximum negative Fxxis observed in the area from above the upper ramp to the upper backstage of hanging wall.Corresponding to this,in the hanging wall anticline,the strains Fxxare positive and decrease from the upper backlimb where the maximum value is smaller than Model A3.Maximum positive Fxxalso produces in the place where the hanging wall anticline meets in the left leading syncline but smaller than in uniform viscousplastic materials (Fig. 7c).The highest viscous-plastic strain is found in the area from above the upper ramp and nearby the upper ramp hinge with an ellipse shape and the maximum value is larger than Model A3 (Fig.7d).

Fig.8 Position

Fig.7 Contours of (a)I1 (b)(J2)1/2(c)xx(d)v,after

of particle

viscous-plastic

250,000

years for rigid footwall model B3

―590―

after 250,000

and rigid footwall

years on

By

following

and Fig.8,the shown

an individual

stress

paths

in fig.9a.When

hinge,a

particle

in J space

the particle

as shown in Fig.5 can be tracked

passes

peak value will appear.The

as

over a ramp

value,especially

the

peak value produced by high ramp is larger than by low ramp.Because of the different length of the ramp,the peak value by h=500m emerges later height.Viscous-plastic strain accumulates stress

status

is on the yield

lower hanging shortening contacts lower

surface.The

wall undergoes

over

the lower

hinge,it

shortening.When

flat

because

is

path

passes over the

to undergo

particle

in the

horizontal

its stress

the particle

continues the

particle

viscous-plastic

the yield surface.As ramp

than by small only when the

horizontal

above the ramp,

Fig.10development of (a)(J2)1/2 (b) Exx in 100 time steps for differentfootwallwith h=500m

Fig.9 development of (a)(J2)1/2(b) Exx(c)tvp 100 time

steps

for different

ramp

(d)traction in

height with uniform

viscous-plastic material

Fig.11 development of (a)(J2)1/2(b) XX (c)traction steps for different Kt with h=500m

― 591―

in 100 time

displacement.In time step 40 when the ramp height is 500m,it reaches the largest value and then trends to similar value approximately. For a structure with a rigid footwall,even though the horizontal extension is smaller,not only the peak value of (J2)1/2 is higher,but also horizontal shortening, extension and the average viscous-plastic strain are larger.The viscous-plastic footwall deforms more smoothly and results in smaller shear effect,however, there is practically no footwall deformation in series of model B,and consequently,the ramp shape remains relatively unchanged (Fig.10).

Fig.12 development time

of (a)(J2)1/2(b) Exx (c)traction

in 100

steps for different rt with h=500m

the stress status falls below the yield surface because of increasing I1 and decreasing (J2)112and,thus,further viscous-plastic strain temporarily ceases.The incremental strain changes from horizontal shortening to extension approximately midway up the ramp.Over the upper ramp hinge,I1 decreases and (J2)1/2increases,and the stress state returns to the yield surface,resulting in additional viscous-plastic strain.This second phase of viscous-plastic deformation is horizontal extension, which is superposed on the earlier phase of horizontal shortening.As the particle moves over the upper flat, (J2)1/2decreases and the stress state falls below the yield surface.After all the viscous-plastic deformation is distinctly episodic.When the ramp height exceeds 300m, the areas of horizontal shortening and extension are classified evidently.On the fault surface, from the development of traction of right low corner node of the triangle element (Fig.9d),the value rises and drops episodically.It rises as it isn't yielding,otherwise drops due to amendment by the viscous-plastic incremental

― 592―

Fig.13 (a)slip displacement(b)backlimb dip

(c)forelimb dip

(d)thickness variation after 250,000 years for different height with uniform viscous-plastic model

ramp

For

different

viscous-plastic though

the

times

of

tangent

stiffness

footwall

when

traction by

produced

MN/m

similar

but

,the

strain

Exx

increase

different

fluid

MN/m,the

peak with

first

50

of

is is

the

however,in s-1

shapes

of

that

to

50

rc

two

but

material

to

relationships

Kt.

same

evolution.The

by (J2)1/2

c=3x10-11

by

s-1,the

models

are

rc

(J2)1/2

more

similar

The

value

of

ramp

height

condition direction

angle

thickening

the

to

forelimb

increase

h.Comparing

with

in

the

with h=500m,

hanging

smaller

with

advanced is

the the there

than

forced

final

initial

ramp

the

later

shallow will

evolution 32•K.According

initial

layer

decrease is

the

or

rc over

and

28%

layer

the

finite

the

it leaves

layer

wall(Fig.13).

the

equivalent

But

when

DISCUSSION

the

In the form of kinematical models proposed by Rich(1934),bed-duplication folding requires:(1) translation of hanging wall rocks sub-parallel to the thrust surface;(2)steps or curves in the thrust surface; (3)continuous contact between hanging wall and footwall rocks across the detachment surface;(4)stiff or rigid footwall.Suppe(1983)added three requirements to constrain the geometry of bed-duplication folds.These are:(5)constant length of beds;(6)planar fold limbs;(7) constant thickness (normal) of beds within planar limbs. Actual fault-bend folds may not develop precisely with the assumptions of parallel behavior, because the kinematic details depend on the mechanical properties of the layers applied.In this paper,the finite element models simulate both fold geometry and the distribution,

•\ 593•\

other

initial

ramp

evident these In

are

fault

creep

effect

are

used,the

be

observed

coefficient the

in

shorter

by

second

shortening,extension also

have

lower,the occurs

larger

to the

after

ramp,the small.On

is

used,the the

ramp

end.If

the

are

more

the

all,

ramp.

of

of

Kt

rc means the

same

stiffness

same

structures

hysteresis or

shape

can

smaller

and

fluid

peak

value strain

viscous-plastic the

shear

means

the

similar.Horizontal

average

of

the very

value

difference.When

tangent

or

evidently.

to

stiffness but

are

will

ramp

shear-effect

tangent

surface

shown

footwall.After

value

of

as

varieties

due

higher

phenomenon by

footwall beginning

and

large

of

are

same,these

invariant

by

degree

above

period.When

larger

fault

finally

steep

increase

varieties

phenomenon

on

decrease

displacement

model,higher

but

is

shortening,extension

forward

dominant

surface

2

A3,there

at the

a viscous-plastic

cohesion

synclines

particle

strain

from is

trailing

the the

arrives

goes

angle

varieties our

of

a rigid

using

addition,

model

advanced

relative

change

than

stronger

of

particle

dip.In

a viscous-plastic

horizontal

hand,when

doesn't

its

particle

their

in

will

viscous-plastic

of

from

Al,there is

wall.If effect

ramp,the

the

angle

angle

but

the

and

in the

but

hanging

increase

range

as h=500m.

shear

decrease.Before

the

forelimb,whereas

models,when ramp

the

affected element

models,layer

model

h=100m

element

increases,the

differences

4

as

of

will

constant

26•K. only

during

dips

forelimb

models.In

is used,the

in Fig.5

the

not

thickening

squeezing

ramp

than and

are element

be

degrees

the

the

24•Kto

finite

geometric

increase decrease

model

depends not

forelimb

some

element h=500m,

from

the

few

final

to

thickening

footwall

ramp

thickness,

of 20%

rc

layer

In

the

a

fault-

the

dip

ramp.In

by

should should

finite

range

would

the

a

finite

during

forelimb

of

of

26.5•Kas

degrees dips

the

geometric

geometry.In

the

initially

backlimb

and

thicknesses

22

The the

larger of

7%

opposite

than is

the

few

increase

31•Kto

the

dip.In

is

geometry,and

model

of

fold dip fb

ramp

a

the

backlimb

dip

fold

fundamentally

although

models,the

the

relate

kinked-hinge

the

by

by

layer

a

to

geometric

those

angular

are

curved

ramp

on

and

velocity

has

decrease

h.

Kt

velocity.

smaller

(5f which the

and of

which

dip with

Kt,rc

increase is

side

traction

which

and

h.When

left

(Fig.1)

to

rc and

model,it of

increases of

relates of

referring bh

variation

increase

each

of

angle of

h.In

because

(26.5•K)

increase

decrease

particles

dip

ramp

displacement

the

of

while

backlimb

the

slip

with

displacement

the

the

folds

are

decrease

thinning

decreases

the

the

thickening

(Fig.12).

It

equal

with

configuration.The

use

is

compared

fold

folds,which

first-mode

when

folds.The

be

fault-bend

hinges

models,it

similar,

produced

will

In

rc.In

of

can

models,the

fold

it

fault-bend

models

generally

bend

in

fault

geometric

models,

produced

more

the

average

s-1,the

are

if

the

the

for

appears

of

traction

=3x10-11

traction r

geometry

are

with

decrease

models

by

models

Kt=1x105

similar

the

by

geometric

models

surface and

the

steps,the

approaches

this

with

material

last

fault

is

of

(Fig.11).For

strain Exx,the

found

close

two

the

.1x10-10

(J2)112

increase

steps,it s-1

shapes

of

strain

rc=1x10-11

the

Kt

h=500m

rc.Horizontal

viscous-plastic the

on

geometry

viscous-plastic of

deformation

6 Kt

larger

of

s-1,

by

(J2)1/2

by

average

when

value

smaller

of

timing

is

of

value

increase

coefficient

with

c=1x10-11

times

lately

the

footwall

surface r

MN/m

3

peak

appears

the

fault and

and

and

and

with

viscous-plastic

lately

shape value

the

Kt=1x105

MN/m

peak

Horizontal strain

by

Kt=1x104

=3x104

on h=500m

ramp

effect or

strain height

is

hysteresis

also

smaller

fluid

coefficient invariant

on fault surface has large

In a word,the regular

but peak value of the second

difference

cohesion

despite

of similar

and creep on fault surface

shape.

On the other hand,

the cohesion

surface

effect for the total system.

have regular

Classic

have

effect for the total system.

relations that

geometry and,

would

models

in which

and creep

suggest

backlimb

not be affected

and the

backlimp forelimb

during

the

increase

dip will decrease

simulates

Fig.14

Schematic drawing of possible deformation mechanisms

sequence

cataclasis

From reference[6],pressure-dependent viscous-plastic deformation can simulate cataclasis and pressure solution creep,so the results of our models can also be used to infer a sequence of deformation mechanisms for a particle moving over a ramp(Fig.14):(1)viscous plastic shortening,(2)shortening,(3)shortening,(4)extension, (5)shortening.From these results,the sequence of deformation mechanisms can be obtained:(1)transportperpendicular stylolites,(2)transport-perpendicular stylolites,(3)transport-perpendicular stylolites,(4) bedding-parallel stylolites with viscous plastic extension, (5)transport-perpendicular stylolites.Kilsdonk & Wiltschko(1988),in a study of the ramp region of the Pine Mountain fault,recognized an early deformational phase characterized by transport-perpendicular stylolites, which may correlate with our stages 1-3.Wiltschko et al. (1985) recognized early transport-perpendicular stylolites,which may correlate with our stage 1,and later bedding-plane slip,which may correlate with our stages 2 and 4.Thus,our model results are consistent with field observations,although the complete suit of deformational stages indicated by these models has not been recognized in the observational studies. 5

material

finite

properties

element

models

to simulate

Throughout

most

of

the fault-bend the

model

that the shear effect,the

shortening,extension,equivalent and advanced

with

both in continuous

fault surface

conclude

degrees would

would

decrease

plastic

results

our

deformational been recognized

which

creep,so

is the

composition

bedding-parallel

shortening model

stages

solution

can be used to infer a sequence

and

observations,although

deformation

are

of of

stylolites

and extension.Thus,the consistent

the indicated

the

with

complete by these

in the observational

models

field

suit

of

has not

studies.

REFERENCES 1)Berger & Johnson:First-order analysis of deformation of a thrust sheet moving over a ramp,Tectonophysics Vol 70,924,1980. 2)Suppe:Geometry and kinematics of fault-bend folding,Am. J.Sci.Vol283,684-721,1983. 3)Kilsdonk & Wiltschko:Deformation mechanisms in the southeastern ramp region of the Pine Mountain block, Tennessee.Bull.Geol.Soc.Am.Vol 100,653-664,1988 4)Johnson & Berger:Kinematics of fault-bend folding,Eng. Gelo,Vol27,181-200,1989 5)Rich:Mechanics of low-angle overthrust faulting illustrated by the Cumberland thrust block,Virginia,Kentucky and Tennessee,Bull.Am.Ass.Petrol.Geol.Vol18,15841596,1934 6)Erickson & Jamison:Viscous-plastic finite-element models of fault-bend folds,Jour.Stru.Geol,Vol 17,No.4,561-573, 1995 7)Zhishen Wu,Yun Gao & Murakami:A finite element model for crustal deformation with large slipping on fault surface, International workshop on solid earth simulation and ACES

CONCLUSIONS We use

a few

thickening

thinning

and pressure

mechanisms

with viscous of

by

viscous-plastic

transport-perpendicular

of

increase

dip.

of our models

deformation

of the

by a few degrees

evolution.Layer

Pressure-dependent

results

dip

to our finite element

the forelimb,whereas

the forelimb

of angular

by the later shallow

dip will

model

a series

dip and forelimb

ramp will keep constant.According models,the

on the fault

displacement

viscous

WG meeting,2000 8)Koji Sekiguchi:Time step selection for 6-noded non-linear

plastic

body

and on the

folding

structures.

evolutions,we varieties

can

of horizontal

viscous-plastic are dominant

joint element in elasto-viscoplasticity analyses,Computers and Geotechnics,vol10,33-58,1990

strain

due to the ramp.

― 594―

(Received April 21,2000)