A Section Sandbox Modeling on the Evolution of Conjugate Normal

Faults

Tianwei Zhou

Hailong Xu and

Shuang Liang

Research Institute of Petroleum Exploration and Development, CNPC, Beijing, China

Email: zhoutianwei@petrochina.com.cn

Keywords: Conjugate normal faults, salt structure, Sandbox modeling

Abstract: Fault systems can impose considerable effects on structural closure concerned to oil accumulation. It is

widely known that conjugate normal faults were developed over extensional basins, but the evolution of the

special fault arrays was seldom reported. The Nanpu Sag, located in the north part of Huanghua Depression

of Bohai Bay Basin, is a Cenozoic petroliferous extensional fault-block sag. Based on the interpretation of

the 3D seismic data in the Nanpu Sag, the geometry of conjugate normal faults were described both in plane

and profile, and the evolution was analyzed using balanced cross-section restoration technique, the results

indicated that the special faults were formed in a very short geological time and also in weak extensional

setting. Further study of the fault system using a section sandbox modeling technique demonstrated that the

conjugate normal faults showing X-style were formed contemporaneously in a homogeneous geologic body

under extension. With the development of extension, new X-style faults were formed sequentially at the

sides of the pre-conjugate normal faults, all the normal faults constitute a complex conjugate style..The

evolution of conjugate normal faults in rift basins has seldom been reported systematically, this study gives

important evidence and planar sandbox model provides reliable kinematic models to further the

understanding of the description of the conjugate normal faults.

1 INTRODUCTION

The fault is a fundermental topic in fault-block basin

research. For advanced analysis of the relationship

between faults and reservoirs, the study for

evolution and deformation mechanism of faults is

essential. In the Napu sag, most former work was

focused on the description and development of fault

system(Liu, 2011; Tian, 2012), but the detailed

analysis aiming at special fault style was seldom

reported in recent years. In this paper, conjugate

normal faults found in this sag were studied.

2 GEOLOGICAL SETTING

The Nanpu sag with 1932 Km

area including

onshore and offshore, is a classical small but rich

petroliferous Cenozoic sag. developed on the

basement of North China block. From the fault

systems map, it is a half-graben basin faulted in the

north and onlapped in the south. The Northwest and

Northeast are bounded by Xinanzhuang fault and

Baigezhuang fault respectively. The two border

faults cut through the basement and controlled the

formation and evolution of the Nanpu Sag(Figure 1).

Within the Sag, the most newly formed normal

faults since Neogene had obvious NNE orientation,

which seemed to be controlled under later single

extension.

The Nanpu sag was in terrigenous sedimentary

environment in Cenozoic time, the strata include:

the second and third members of the Shahejie

formation in Eocene(Es

2+3

); the first member of the

Shahejie formation in Eocene and

Oligocene(Es

);the third member of the Dongying

formation in Oligocene(Ed

) ;the second member of

the Dongying formation in Oligocene(Ed

) ;the first

member of the Dongying formation in

Oligocene(Ed

) ;the Guantao formation in

Miocene(Ng) ;the Minghuazhen formation in

Miocene(Nm) and Quaternary.

Zhou, T., Xu, H. and Liang, S.

A Section Sandbox Modeling on the Evolution of Conjugate Normal Faults.

In Proceedings of the International Workshop on Environment and Geoscience (IWEG 2018), pages 219-222

ISBN: 978-989-758-342-1

219

Figure 1: The fault systems of top nm in the Nanpu Sag.

3 FAULTS EVOLUTION

ANALYSIS

Based on results of structural interpretations of 3D

pre-stack time migration data, structural styles were

analyzed in the Nanpu Sag. By the application of

balanced geological sections methods, restorations

of 29 geological sections with decompaction were

finished and Cenozoic deformation phases were

accordingly separated.Only extensional structural

styles were found in the Nanpu Sag. There are

complex structural styles in local structural belts

mainly including X-pattern, Y-pattern. The

restoration also suggested that the X-pattern faults

were formed since the deposition phase of

Nm(Figure 2). Although the X-style is complex,

almost all the faults in the style were developed in a

relative short geological time. Confined to the

resolution of strata classification, the detailed

development of X-style faults is still not clear, but it

was formed from late Cenozoic movement. It was

concluded that the lower crust in the Nanpu sag

undergone pure shear deformation since Neogene,

this mechanism can give a reasonable explaination

for the formation of the symmetrical pattern of new

faults in sedimentary cover(Figure 3).

Figure 2: Restoration of a main geological section in the

Nanpu sag.

Figure 3: Fault formation mechanism of different models

in the Nanpu sag. (a.Paleogene; b.after Neogene).

IWEG 2018 - International Workshop on Environment and Geoscience

220

4 MODEL DESIGN

Sandbox modeling, as a form of physical modeling

has proved to be an effective method for the study of

deformation mechanisms of extensional

basins(McClay and White, 1995)

Figure 4: Sketch of side view experimental model.

It was concluded that X-style faults as conjugate

normal faults, may happen easier in a very

homogeneous deformation under extension. For the

sake of homogeneity and clarity, many sandbox

modelings were conducted to determine the length

between the walls and the thickness of sand layers.

The eventual length was designed 14 cm and the

total thickness of sand layers was placed

20cm(Figure 4).

Loose quartz sands have been proven to be the

ideal material for the physical simulation of brittle

deformation in the shallow crust . The sands used in

the experiments are 0.3-0.4 mm in diameter, with

inner friction angles of 31°. In the models, one layer

of rubber sheet is used for deformation transfer

media at the basal of the sag area and connected to

the ends of the movable walls respectively. The

rubber sheet will be gradually stretched as the

motor-driven walls moves outwards, and normal

faulting will take place in the overlying sand layers.

The displacement velocity is 2.58×10

-3

s/cm and the

total displacement is 3.5 cm. The model has been

tested more than twice and similar results have been

obtained. The experiments were undertaken on the

tectonic deformation physical modeling

experimental apparatus of China University of

Petroleum, Beijing.

Although the Nanpu Sag had been controlled by

the main syndepositional faults during Cenozoic

period, for the sake of the observation of the

framework, all experiments omitted the

syndeposition process but the results could not be

affected (Diraison, et al., 2000; Keep, 2003).

5 MODEL RESULT AND

DISCUSSION

After 1 cm of extension displacement, two crossing

faults with opposite inclination appeared, and

constitute the X configuration, but still remain

obscure, the lower part of the X-style faults showed

larger displacements than the upper part, it meant

the deformation was conducted graually from

basement to cover. After 2 cm of extension

displacement, a new set of faults with opposite

inclination cut the upper part of pre-X-style faults,

all the faults constitute complex X configuration;

After 3.5 cm extension displacement, the newly

formed faults were developed at the sides of pre-

faults and cut the upper part of X-style faults

continuously. It can be imagined that the newly

shallow faults would appear with the further

extension, more and more complex X-style faults

would be shown in the sandbox modeling(Figure 5).

Figure 5: X-style faults sequence of the sandbox modeling.

6 SUMMARY

The Nanpu sag is a classical extensional basin

developed in Cenozoic time, X-style faults as a basic

structural style were developed since the deposition

phase of Nm.

It is known that almost all the X-style faults in

the style were developed in a relative short

geological time, confined to the resolution of strata

classification, the detailed development of X-style

cannot be restored by the application of balanced

geological sections method. The sandbox modeling

reproduced the development of X-style faults, it

A Section Sandbox Modeling on the Evolution of Conjugate Normal Faults

221

discovered that the single X-style normal faults were

formed easily in relative narrow geobody under

extension because of the relative homogeneous

geological background. Simple X-style normal

faults were developed under relatively weak

extension while the complex X-style normal faults

were formed under further extension. It was

concluded that the complex X-style faults in the

Nanpu sag were controlled by pure shear

deformation at the lower crust since Neogene.

ACKNOWLEGEMENTS

We would like to show our deepest gratitude to Dr.

Jianxun Zhou from China University of

Petroleum(Beijing), a respectable scholar, who

provided me with valuable guidance in this paper.

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(in Chinese)

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