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Journal of Geoscience,  
Engineering, Environment, and Technology 
Vol 6 No 4 2021 

 

206  Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 

RESEARCH ARTICLE 
 

Understanding Mud Volcano System Using Hele-Shaw (H-S) 
Experiment: Seismic Confirmation at East Java Mud Volcano  

Muhammad Burhannudinnur1*, Dardji Noeradi2 
1 Department of Geological Engineering, Universitas Trisakti, Jakarta, Indonesia. 

2 Department of Geological Engineering, Institut Teknologi Bandung, Bandung, Indonesia. 
 

* Corresponding author: burhan@trisakti.ac.id 
Tel.:+62811836263 
Received: Oct 18, 2021; Accepted: Dec 27, 2021. 
DOI: 10.25299/jgeet.2021.6.4.7889 

 
Abstract 

Numerous researchers have carried out studies on the mud volcano system in East Java. However, there have been no experiments on 
the mud volcano system's mechanism, including overpressure confirmed by direct subsurface data. Therefore, this study aims to directly 
evaluate the mud volcano system's mechanism using the Hele-Shaw (H-S) experiment with the subsurface data confirmation. The H-S 
experiment utilized four primary materials: quartz sand diameter below 250 µm and 320 µm to analogize the porous layer. Gypsum flour 
clay is the ductile layer, while mud from the Kuwu and Kesongo Mud Volcanoes is the original material from nature. Wax repres ents 
impermeable material. The sealing layer is made of wax, and oxygen represents the natural fluids of the rock formation. The overpressured 
zone is created by pumping oxygen into a layer of quartz sand covered by a wax as an impermeable layer. Pressure is measured digitally, 
and the process is continuously recorded to produce traceable data. Each material was experimented on individually to determine the 
critical phase characteristics, valve fault structure geometry, and validation with seismic interpretation. The results indicate that the 
critical phase of the mud volcano system is characterized by the dome structure at the surface, with high intensify of gas and oil seepage. 
Piercement structure geometry is shown by plumbing of fluidization zone, which becomes shallower than before. Furthermore, each 
material's piercement structure geometry shows a consistent pattern, with differences in the density of the fault and pressure structures. 
Thus, the H-S experiment's validation with seismic interpretation shows a similar geometry in pressure structures and valve faults as the 
mud volcano system's migration paths. 
 
Keywords: mud volcano system, Hele-Shaw, overpressured, valve fault, critical phase 
 

 
 
1. Introduction  

The process of a mud volcano system from the 
formation of source material rock, migration to the 
eruption, and its associated structures needs to be 
adequately understood. Analogous experiments with hele-
shaw allow us to see the process of the occurrence of a mud 
volcano system and describe the geometry of the evolving 
structure to be modeled. The geometry model of this 
structure will be compared with the geometry from below 
the surface using seismic data. This analog experiment 
assumes natural conditions are represented under these 
modeling conditions. In addition, the initial parameters of 
the experiment exclude the effect of initial temperature and 
pressure. Subsequently, The elements and processes in the 
generative, migration, and extrusion subsystems were 
formulated. 

East Java is an area where research on mud volcano 
systems has often been carried out, including a study by 
Satyana on mud diapir and mud volcano around East Java 
to the Madura oil and gas fields, especially in the "F" field 
(Satyana and Asnidar, 2008). Meanwhile, Burhannudinnur 
discussed the characteristics of a unique mud volcano in 
East Java, including within the research area, and discussed 
the Kradenan Mud Volcano complex in great detail in terms 
of exploration prospects and risks (Burhannudinnur, 2012; 
Burhannudinnur et al., 2012). Mud gas play is a new 
exploration play for unconventional gas that can be found 
associated with the mud volcano system (Burhannudinnur, 

2019). The mud volcano system in the Kradean and 
Kesongo areas has a potential geohazard risk. The area and 
depth of the potential geohazard risk area can be predicted 
by integrated analysis of the strain ratio and sedimentation 
rate distribution (Burhannudinnur, 2020) 

An analog experiment continually develops to explain 
geological symptoms of structure-tectonics, sedimentation, 
and ground motion. Previous studies conducted a mud 
volcano analog experiment through the simple sandbox and 
fluid experiments. Generally, this experiment uses the 
principle of buoyancy, as in the diapir model. According to 
Price et al., 1990, analogous experiments of low-density 
materials' motion in high-density materials are an early 
concept developed for diapir modeling. In the sandbox 
experiment, the mud volcano material was modeled with 
silicon, for instance, salt diapir (Letouzey et al., 1990; 
Talbot, 1995). Thus, this modeling provides an overview of 
the pressure structure using diapir but cannot explain the 
fluid and pressure present in the mud volcano or the 
eruption mechanism. 

 An analog experiment was conducted with Hele-Shaw 
(H-S) to simulate the mud volcano system as well as 
extrusion mechanism, provide an analog enabling easier 
understanding of the extrusion process in nature, and as a 
validation test for seismic interpretation. Thus, the H-S 
modeling's results are the pressure structure and valve 
faults' geometry models and several simulations of the mud 
volcano extrusion mechanism. 

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Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 207 

 

The Hele-Shaw (H-S) method is a thin glass box 
modeling, enabling the processes inside the glass box to be 
observed visually. H-S boxes are often used in material 
modeling to test physical material properties while 
sprayed, flowed, or under a specific temperature as well as 
pressure (Nermoen et al., 2010; Rigord et al., 2005). 
Researchers introduced this method for modeling glass 
grains' response to pressurized gas flow (Johnsen et al., 
2008). The experiments by Rigord et al. (2005) developed a 
tool to study the response of a thin glass grain layer 
immersed in a slow-flowing liquid under controlled 
pressure, and the tool is designed to allow liquid flow from 
bottom to top. Subsequently, the liquid flow rate is 
measured and controlled to determine the turbulence 
effect. The thin layer of glass grains becomes unstable and 
unbalanced with increased liquid flow. This increase does 
not lift the entire thin layer of glass grain but forms a 
channel or column of the granular fluidization zone, 
connecting the bottom and top. The glass grains emerge to 
the surface to form eruptions similar to jets of water, 
deposited on the surface, with a hole diameter about 32 
times the grain size.  

Nermoen et al. (2010) also designed an experimental 
tool to study the fluidization process. The H-S device in this 
study was vertically oriented, filled with 250 µm glass 
beads, and injected with pressurized gas, with variations in 
the glass grain layer thickness and inlet diameter. 
Consequently, the fluidization zone forms a divergent cone 
in the form of a pressure structure. The surface's 
morphological characteristics on the pressure structure 
have similarities to morphology in nature, including mud 
volcanoes, hydrothermal, kimberlite pipes, or geysers 
symptoms. 

Modeling with the Hele-Shaw (H-S) method implies 
making a tool intended to model the mud volcano system 
and obtain an overview of the valve fault formation 
mechanism, geological structural geometry of the mud's 
motion through the layer above, observe the geometry and 
material motion from the overpressure zone to the mud 
volcano extrusion. Furthermore, Hele-Shaw is a vertical 
modeling method assumed to represent the geological 

section of the research area. The initial condition of H-S 
modeling is static, and the pore pressure is under 
hydrostatic conditions. 

2. Methodology 

2.1. Hele-Shaw Design and Manufacture  

In this study, the H-S equipment and methods were 
designed and modified based on reference tools provided 
by Rigord et al. (2005), Johnsen et al. (2008), and Nermoen 
et al. (2010). 

The main equipment consists of an H-S wall, support 
table, inlet, hose line, and a gas cylinder. Meanwhile, the 
supporting equipment includes a pressure measuring 
instruments, computers, BSR software, on-screen video 
recorders, cameras, digital scales, levelers, funnels, pipes, 
and calipers. The H-S wall is a tool made of two parallel 
glasses 100 cm long and 75 cm tall, separated by a distance 
of 0.8-1 cm at the bottom and closed at the two sides 
(airtight), and open at the top. Furthermore, the material, 
particularly the compressed gas, is modeled outward rather 
than out of the three sides. An inlet was installed 8 cm from 
the bottom to prevent gas from flowing along the sand or 
equipment bottoms. Fig. 1 shows the Hele-Shaw modeling 
scheme and set of tools and an example of the experiment 
implementation. 

2.2. Selection of Material Types 

The material selection and use in modeling referred to 
the reports of several related research, including sandbox 
modeling at the Geodynamic Engineering Geology 
Laboratory, Faculty of Earth Sciences and Technology, 
Bandung Institute of Technology, referring Mazzini et al., 
(2009). In previous studies, material selection considered 
several factors: low cohesiveness and bearing capacity, 
brittle and ductile materials, easy-to-form structures, high 
porosity, safety, and ease of obtaining materials. Table 1 
shows some materials variations used in H-S modeling and 
sandbox modeling, while Fig. 1 shows a simplified diagram 
of H-S modeling tools installation. 

Table 1. Material variations in H-S modeling and sandbox 

Researcher Material Type Material layer 
density (gr/cc) 

Material 
density (gr/cc  

Grain Size 
(µm) 

K 
(mD) 

Porosity 
(%) 

Hele-Shaw 
(Nermoen et al., 
2010) 

glass granules 1,547 2,460 280±50 120 37,11 

Oxygen      

Sandbox (Sapiie 
and Hadiana, 2007) 

quartz sand 1,500  250   

Hele-Shaw (Rigord 
et al., 2005) 

glass granules 1,530 2,190 80-400 
and 280±50 

26 30,14 

water      

Sandbox 
modification 
(Mazzini et al., 
2009) 

silica granules   50-100   

Chinese clay    low  

glass granules   118-380   

air      

This research  quartz sand 1,500  250-320   

Mud from the Kuwu and 
Kesongo mud volcanoes 

1,453 2,560 
(dry) 

1-50   

Oxygen      

wax      

gypsum   <100   

 



 
208  Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 
 

 

Fig. 1: Simplify diagram of the main H-S modeling tools 
installation (A) Hele-Shaw kit with quartz sand filling; (B) 

Pressure cable with digital pressure record; (C) High-pressure 
oxygen gas cylinder. 

The materials used in this experiment were assumed to 
represent natural material conditions, and the details are 
outlined below. 

(1) Quartz sand below 250 µm and 320 µm diameter to 
model layers with high porosity, low cohesiveness, 
low bearing capacity, assisted by the Geodynamic 
Laboratory, Geological Engineering Department, 
Faculty of Earth Sciences and Technology (FITB), 
Bandung Institute of Technology. 

(2) Gypsum flour was assumed to represent a more 
ductile layer and was purchased from a chemical 
store. 

(3) Mud from the Kuwu and Kesongo mud volcanoes 
containing different water and material represent 
the actual material condition in nature. Mud from 
Kuwu (sample no B-80) has a composition 
dominated by smectite, 95% clay grains, and 
inherent moisture by 11.5%. Meanwhile, mud from 
Kesongo (sample no B-81) is more granular, has 
almost equal kaolinite and illite content, and has a 
6% inherent moisture. 

(4) Waxes were obtained from chemical shops and used 
to create impermeable coatings or insulation. 

(5) Oxygen represents natural fluids as material 
released during formations to create an 
overpressured zone for safety reasons and is not 
adsorbed by granules. 

2.3. Equipment Performance Testing 

This test is necessary to determine the leakage and the 

H-S equipment's ability to accept pressure, the sensitivity of 

pressure changes towards the experimental material 

layers' height variations, and the distance between the glass 

at the middle and edges. The test measured the pressure at 

different material layer heights for the same material type 

from the inlet top end. The material used was loose quartz 

sand measuring 250 µm with layer height (h) measured 

from the inlet end ranging between 10 and 40 cm. 

Data recording began with assembling the modeling 

equipment for this test, as shown in Fig. 1. The supporting 

equipment to be made is outlined below. 

(1) Digital Extech 750 (data logger) pressure meter 

with 200 Pa resolution for digital pressure 

measurement. 

(2) Laptops and software required to record data. 

(3) Camera, with the ability to record 30 frames per 

second for video recording to record geometry 

and process the fluidized zone 

(4) High pressure oxygen gas cylinder (200 kg / cm2). 

(5) Flexible pipe with a size of 4 mm, hole diameter 

2.5-3 mm, and able to withstand pressures up to 

50 psi along with the connector. 

(6) BSR software to record and save the data 

(7) Preparation of other supporting tools, including 

digital scales and rulers. 

(8) Preparation of modeling materials (quartz sand, 

mud, and wax). 

In each experiment, the material used was weighed to 

ease the thickness control, then poured slowly through the 

funnel from the top to the desired height (h), and measured 

from the inlet's end. The sand is leveled rather than 

compacted according to height and made layer by layer as 

required. Subsequently, high oxygen gas pressure was 

injected into H-S through the inlet. The oxygen flow rate (Q) 

was controlled at a constant flow rate. The valve was 

opened slowly to avoid turbulence in the material, located 

near the flow meter, 8 cm away from the gas cylinder. 

Meanwhile, the pressure (P) was recorded at a T-junction, 8 

cm away from the inlet, using an Extech pressure meter. In 

this modeling, the gas input was controlled manually, while 

the pressure variations measurement was carried out 

automatically by an Extech pressure meter. In addition, 

digital images were recorded at a rate of 30 frames per 

second with the high-resolution Olympus VG-140 camera; 

14 megapixels; 5x wide; and optical zoom by 4.7-23.5 mm, 

and O2 entered slowly, increasing until deformation 

occurred in the layer above. The pressure in the model 

increased to form a high pressure or fluidization channel up 

to 8.5 kPa, before erupting, then reducing to 7.0 kPa. Critical 

phase condition refers to the time of highest pressure 

before erupting. Fig. 2 shows an example of the recording 

results and the pressure profile. The equipment's test 

results did not leak, the gas continued to flow, and the 

distance between the Hele-Shaw glass wells did not change. 

Meanwhile, the subsequent test measures pressure at 
various sand heights to test the equipment and material 
sensitivity. The tool has a sensitivity and readiness to 
perform further experiments, even with the increase in 
layer height thickness or pressure. The distance between 
the glass walls was measured with a caliper to determine 
the distance stability during the test. The H-S equipment is 
then suitable for use in cases where there are very small or 
no changes in distance. 

Fig. 3 shows the test results, and the graph of pressure 
on material layer height shows a linearly proportional 
relationship with regression reaching 0.917. This high 
regression indicates that the Hele-Shaw model equipment 
is functioning correctly and sensitive to pressure, with 
changes in the layer height. The sediment height (h) further 
increases critical pressure, while the distance between the 
glass in the middle extended less than 0.02 mm at a 32cm 
layer height. Thus, the change in length is minimal, 
indicating the glass is strong enough to withstand the 
material and consequent pressure; therefore, there is no 
significant volume change in the Hele-Shaw tool. 

A 

B 
C 



 
Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 209 

 

 

Fig. 2: An example of the pressure profile experiment (P) results on the material height measured from the inlet tip to the material layer's 
surface (h = 17 cm). This figure shows the development of quartz sand behavior during the initial oxygen injection until eruption, from 1s 

to 26s. The model's pressure increases to form a high pressure or fluidization channel until 8.5 kPa, before the eruption, followed by a 
reduction to 7.0 kPa. 

 

Fig. 3: Graph of equipment testing. The pressure increases as the 
layer height (h) get thicker, indicating the equipment did not leak 

during the experiment and is suitable for modeling. 

3. Result and discussion 

3.1. Experiment with Material Variations 

This experiment aims to determine the material 

response to the injection of compressed gas from the 

bottom. The method replaces the experimental material 

and records pressure data and a video from the beginning, 

where oxygen is first injected until an eruption occurs. 

Experiments were conducted on four materials, including 

80 µm, 250 µm, and 320 µm size quartz sand, gypsum, and 
mud from the Kesongo and Kuwu mud volcanoes. 

The four materials showed the same response after 

pressure reached a critical condition by forming pressure 

and dome structure on the surface (Fig. 4). However, the use 

of mud in this modeling responds differently from the other 

three materials. The pressure structure and fluidization 

zone geometric developments are not observable while 

using mud. The mud material is not used to model the 

pressure structure geometry in the subsequent stage. 

3.2. Critical Phase Characteristics 

The H-S section's critical pressure pattern and 

geometric expression are observable in this experiment. 

Based on experiments and observations from the model, the 

critical pressure phase's characteristics in the H-S model 

are obtained, as outlined below. 

(1) The release of small gas and sand eruptions at 

numerous points, with the gas eruption's position 

on the surface changing and a fluidization channel 

visible below the surface. 

(2) The dome structure found on the experimental 

layer's surface is associated with a lot of gas 

seepage. The fluidization zone's position becomes 

shallower in-depth, increasing to a more 

superficial level. In the H-S cross-section, 

fluidization channels are seen by pressurized gas 

passage 

Fig. 5 illustrates the model characteristics in the critical 

pressure phase, and these characteristics apply to field and 

subsurface data in an integrated manner. 

 



 
210  Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 
 

 

Fig. 4: Experiment with four types of materials. The result forms the same structure at a critical pressure, a dome structure on the 

surface. 

 

Fig. 5: Characteristics of a critical phase on the surface. (A) A small gas burst at several points, often with a pressure structure at the 
bottom. (B) Gas seepage next to the sloping dome, resulting from the breakthrough. (C) Another example of gas seepage. (D) Dome 

structures on the surface are associated with gas seepage. 

3.3. The Geometry of Pressure Structures 

The development of pressure/piercement structures 

has been tested in three materials, 250 µm and 320 µm 

quartz sand and gypsum. Fig. 6. A to L show the 

development from initial conditions to eruption in the three 

materials. The pressure structure's detailed geometry for 

the three materials shows a consistent pattern 

development, with differences in the fault and pressure 

structures' densities and widths. Therefore, structure 

intensity is tighter in finer gypsum and quartz sand (250 



 
Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 211 

 

µm). In gypsum material, a fan-like structure tends to 

develop and occur in more than one fluidizing channel. 

Repeated experiments were carried out by recording 

from the start of oxygen injection to material extraction to 

determine the pressure structure's consistency. 

Furthermore, a description consistent with the presence of 

a positive pressure structure similar to a "positive flower 

structure" was obtained.  

 

Fig. 6: Fault geometry variations of piercement structure in eruption and post-eruption models for various experimental materials. (A, B, 
and C) fault geometry in 320 µm quartz sand. (D, E, and F) fault geometry in 250 µm quartz sand. (G, H, and I) fault geometry in gypsum. 

(J, K, and L) show details of fault geometry patterns in each material. Surface subsidence occurs after the eruption but remains an 
overpressured zone in the deep zone. 

3.4. Validation of Seismic Interpretation with Hele-
Shaw Model 

The validation model was performed using a modeling 

scale of 1 cm representing 100 meters. The thickest 

sediment in Kradenan is 3,000 m (Burhannudinnur, 2012); 

however, the Sidoarjo counterpart is not obtainable from 

seismic data but was estimated to be over 4,000 m from the 

region to 15,000 feet (Kusumastuti et al., 1999; 

Burhannudinnur et al., 2012). In addition, the material layer 

height measured from the top of the inlet is 30 cm. Hele-

Shaw modeling is basically vertical and close to 2D, 

however, in this experiment, a lateral scaling referring to 

sandbox modeling, where 1 cm = 1 km was used, and the 

length of 100 cm represents a route passing through 

Kradenan or Sidoarjo areas (40-70 km).  
Validation of valve fault geometry in Sidoarjo is 

represented by XX-07 (Fig. 7) and XX-126 (Fig. 8) seismic 

lines. Fig. 7 shows the main fault in green. The main faults 

develop into small ones while cutting the strong reflection, 

forming a pattern similar to a small fan's radius. The seismic 

reflection forms a positive curve as a pressure structure. 

According to Fig. 7, the seismic section's fault and pressure 

structure show similar geometries and patterns compared 

to the geometry of the modeling results. Meanwhile, Fig. 8 

shows the seismic interpretation's validation, using an 

analog model with Hele-Shaw in the Sidoarjo area, for 

random reflection patterns and pressure structures similar 

to shear fault geometry with positive flower structure 

geometry. 

The formation of seismic pressure structure in the 

Kradenan area was selected by two routes, XX-08, under 

Banjarlor and Cangkringan (Fig. 9), and XX-09 (Fig. 10), 

under Crewek. Fig. 9 shows a vertical channel with random 

characters, representing a mud material supply channel 

and a pressure structure, closely similar to the H-S model. 

Also, the XX-09 seismic line through the Crewek Mud 

Volcano is highly similar and a fitting representation of the 

seismic and model from Hele-Shaw. 



 
212  Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 
 

 

Fig. 7: (A) Valve fault in seismic data XX-07, Sidoarjo. (B) valve faults in H-S models. The upward pressure pattern obtained by 

pushing/piercing the material through the main fault causes a series of valve faults. Minor faults are closely similar between seismic and 

H-S models. The pressure migration causes a new valve structure above other points (green circles) occurring in models and seismic.  

 

Fig. 8 (A): Fault's development on the is possibly modeled with H-S. (B) Interpreted seismic W-E Banjarpanji-1 Well ((Tingay, 2014)). (C) 

Valve fault geometry/piercement structure around BJP-1. (D) Interpreted seismic data S-N BJP-1well (Sawolo et al., 2009). 

 



 
Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 213 

 

 

Fig. 9: (A) Mud volcano system at Madura offshore (Istadi et al., 2012). (B) Mud volcano system in H-S model. (C) Seismic line XX-08 

onshore seismic around Mv. Kuwu, East Java. They have a similar structural pattern, vertical plumbing from random reflection with 

dome or pressure structures at the top, bounded by main faults.  

 

 

Fig. 10: The interpreted seismic passing XX-12 (A) through the Crewek Mud Volcano shows seismic's random zones matching the H-S 

model geometry (B, C red box). 



 
214  Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 
 

3.5. H-S Modeling of Overpressure Materials Lateral 
Movement 

H-S Lateral Movement modeling aims to understand the 
occurrence of lateral migration of overpressured materials. 
The initial condition of the model is to make two inlets; the 
first inlet is at the bottom of the model, while the second is 
on the side of the sealing layer above the overpressured 
layer. This second inlet represents a minor fault as a 
migration path. The position of the minor fault (second 
inlet) has an impermeable layer above the porous layer 12 
cm from the projection of the first inlet.  

Based on the results, after being injected with oxygen, 

the quartz sand layer under the sealing layer slowly forms 

an overpressured zone between the quartz sand and wax 

layers. Furthermore, the push or flow changes upward and 

moves sideways until a small fault is found. These faults in 

the sealing layer become channels for the overpressure 

material to rise and push upward, forming valve faults and 

pressure structures, then moving and extruding to the 

surface (Fig. 11). Lateral movement is also caused by 

compacting differences in the same material layer. Fig. 12. 

B shows the difference of gypsum compaction at the middle 

and edges, causing the gas not to penetrate sideways, then 

upwards, rather than vertically. 

Lateral movement of material with overpressure in 

nature also occurs under the surface. For instance, the 

seismic route XX-10 passes through Kesongo Mud Volcano, 

and in the Ngimbang Formation, overpressure and 

connection by faults form the Kesongo Mud Volcano on the 

surface. This fault also acts as an overpressure migration 

route into the zone above. Meanwhile, the Tawun formation 

forms a large overpressure zone, reaching 7 km below the 

younger formation sealing layer. In the Tawun formation, 

the overpressure zone is characterized by a random and 

blurry reflection pattern, forming an irregular geometry 

similar to a chamber or pocket. Another distinctive feature 

is the presence of Vbright around the channel and minor 

faults and polygonal faults in the Tawun formation outside 

the reflection pattern random geometry (Fig. 13). 

According to Fig. 14, the Hele-Shaw modeling confirms 

overpressure conditions are spread under the sealing layer 

before finding faults or fractures or moving forward in 

search of a weaker zone. 

The presence of an overpressured zone in the Ngimbang 

Formation from random seismic reflection data supports 

the existence of fossil data from rock fragments with 

Oligocene ages, and this age is in accordance with the 

Ngimbang-Kujung Formation. Also, the main faults serving 

as the material supply channel are seen in the seismic data 

of mud volcanoes and are supported by petrographic data 

of rock fragments with scour, micro folding, and stylolite 

structures, showing strongly deformed rock samples. 

 

Fig. 11: (A) Initial model of H-S sand layer sealing layer insert (green wax), minor fault as the second inlet, with h- 22 cm. (B-E) High-

pressure gas penetrates the layer below. (F, G) The gas presses move sideways and concentrate under the seal. (H) The gas penetrates 

minor faults, second inlet. (I) Fluidization in the second inlet.  

 



 
Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 215 

 

 

Fig. 12: (A) Detailed figure of the movement of the overpressure material. (B) overpressured material moves along weak zones, even in a 

homogeneous material (gypsum), probably controlled by differences in gypsum compaction at the middle and edges. 

 

Fig. 13: (A) Seismic cross-section, random reflection channel pattern, V-bright, and random/chaotic reflection. (B) Velocity interval 

section, white is the lowest velocity while red-purple are high velocity (Burhannudinnur et al., 2021) 

 



 
216  Burhannudinnur, M. et al./ JGEET Vol 6 No 4/2021 
 

 

Fig. 14: The high-pressure zone H-S model pushes the sealing 

layer (thick mud) upward forms an anticline structure at the 

bottom seal layer. The model shows the high-pressure layer 

unable to break through the seal, h = 30 cm, at P = 17 kPa (2.5 psi). 

4. Conclusion 

The critical phase and the pressure structure pattern 
characteristics are shown in the dome structure pattern as 
the fluidization zone becomes shallower than the source. 
Each material's pressure structure geometry shows a 
consistent pattern, with differences in only the fault and 
pressure structure densities. In addition, the H-S 
experiment's validation with seismic interpretation shows 
the same geometry in the form of pressure structures and 
valve faults as a migration path from the mud volcano 
system. The valve's geometry and fault pattern are only 
observable in quartz or gypsum sand, but not the mud. 
Thus, H-S modeling is suitable for validating the fan-like 
fault structure's geometric pattern in a mud volcano system 
at seismic. 

Acknowledgments 

Acknowledgments are addressed to the Department of 
Geological Engineering, FTKE Trisakti University, and the 
authors' colleagues who cannot be mentioned one by one 
who has provided input and discussions, PT. Pertamina EP 
for the research permission, all parties who helped in this 
research. 

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