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Research Article | | Peer-Reviewed

Geo-environmental Study of Soils Within the Double Landslide Area of Foreke-Dschang (Cameroon Western Highlands)

Evariste Désiré Moundjeu* Achille Ibrahim Bienvenu Primus Azinwi Tamfuh Georges Simplice Kouedeu Kameni Rodrigue Kouotetang Rodrigue Kenne Yap Hassan Mfouapon Joseph Guepi Vounang Zetekouang Emile Temgoua
Published in Earth Sciences (Volume 14, Issue 5)
Received: 29 July 2025     Accepted: 12 August 2025     Published: 17 October 2025
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Abstract

Humid tropical mountainous areas are often vulnerable to mass movements and thus necessitate an in-depth study for best management practices. The aim of this work is to characterize the soils of the Foreke-Dschang (Cameroon Western Highlands) double landslide area on a geotechnical and physico-chemical basis. In effect, this area recently experienced a tragic double landslide on 5th November 2024 causing considerable human and material loss. Field work involved landscape analysis, geological description, soil prospection and sample collection (rocks and soils). In the laboratory, rock thin sections were cut and observed under the microscope while soil samples were analyzed by standard procedures. Results indicate that the primary parent material of the soil is a granite-gneissic (basement). The geotechnical study of the soils shows a silty clayey texture, high porosity (>29%), high water saturation rate (>60% water), low cohesion (<0.5 bar) and high angle of internal friction (18°–25°). Such characteristics, alongside steep slopes (>30°), exceptionally heavy rainfall (>2500mm/year) in 2024, low (<2%) organic matter content (due to reconversion of the forest into cropland), vibrations generated by heavy traffic on the National Road No. 4, inappropriate agricultural practices on the slopes and absence of water drainage structures are at the origin of a translational type landslide. The implementation of drainage measures, slope reduction and grassing, construction of retaining walls and geotechnical developments to reinforce the stability of slopes along the road and the implementation of appropriate agroforestry practices are highly recommended to control soil movement.

Published in Earth Sciences (Volume 14, Issue 5)
DOI 10.11648/j.earth.20251405.12
Page(s) 184-195
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2025. Published by Science Publishing Group
Previous article
Keywords

Landslide, Foreke-Dschang, Slope Stability, Granite-gneiss, Cameroon Western Highland

1. Introduction
Humid tropical mountain ecosystems are most susceptible to mass movements, such as landslides, rockfalls, etc.
[14]
. The Cameroon Western highlands are prone to landslides
 [2, 7, 11]
; the most recent and spectacular one is the landslide of 5th November 2024 that occurred at the Foréké-Dschang escarpment. Here, a section of the cliff collapsed in just a few seconds, in two stages, at 10:30 a.m. and at 2:30 p.m. The Foreke-Dschang escarpment is under heavy anthropogenic stress due to conversion of forests into cropland and heavy traffic on the National Road No. 4 (Dschang-Douala road). This escarpment has a vertical elevation difference of 700 m between Dschang town (1400 m) and Santchou (700m) over a distance of 12km. With a volume of 8000 m3 of earth, the double landslide cut the regional road at kilometer point 17 (pK17) linking the towns of Dschang and Santchou. The first landslide did not cause any deaths or injuries, but the second one, which surprised rescuers engaged in clearing the road and road users waiting for these clearances, caused heavy damage (Technicians died, their equipment and several parked transport vehicles were buried). Numerous, although unconfirmed, testimonies reveal that four coaster-type vehicles, three picnics and numerous motorcycles remained under the heavy earth debris. Furthermore, the direct damage is estimated at several millions of CFA francs, to which must be added the damage of the National Road No. 4. This study is part of a general research program on mass movements in the Cameroon Western highland. The work aims to perform a geological and geotechnical characterization of the soils of the site of the double landslide of the Foreke-Dschang escarpment. The results obtained will enable to elucidate the possible causes of the landslide and to prevent or mitigate future catastrophies caused by land movements.
2. Materials and Methods
2.1. Study Site
Figure 1. Aerial view of the Dschang-Foréké cliff.
The Foreke-Dschang escarpment is located 10 km in southwest Dschang toen. It shows a vertical difference of 700 m between Dschang (1400 m) and Santchou (700 m). An aerial view of the cliff shows anthropogenic activies such as agriculture on the slopes and gallery forests along the watercourses (Figure 1). The climate temperate and depends on a unit of factors that are linked not only to the relief and the exposure of this region to major atmospheric currents. It also depends on its geographical position and distance from the sea
[2]
. The annual precipitation is abundant (1400- 2500 mm) with peaks between July and October, decreasing from South to North while increasing in the vicinity of the mountain ranges. The drainage network is linked to the relief of the landscape
[2]
. The forest and wooded savannah vegetation is heavily anthropized by a predominantly agricultural population
[9]
. Geologically, the region is dominated by the Pan-African granito-gneissic basement which is intruded by Tertiary to recent volcanics (rhyolitic, trachytic and basaltic flows, and basaltic and ignimbritic projections)
[2]
. The geomorphology of the region, the geological nature and age of the formations, as well as tectonic action combine with climatic conditions and sometimes anthropogenic actions to make the highlands of Western Cameroon a region at high risk of mass movement
[1]
. Throughout this region, scars of old land movements and signs of aborted or ongoing movements are observed
[2]
. The soils are classified into four categories
[9]
: poorly differentiated soils or lithosols developed on the crystalline basement are observed at the top of the interfluves and on very steep slopes; very desaturated ferrallitic soils on basement, developed on slopes less than 13% and at the foot of steep slopes; Moderately desaturated ferrallitic soils on volcanic rocks observed on the slopes of the interfluves; and more or less saturated lowland hydromorphic soils, more or less humiferous, located at the bottom of slopes and strongly influenced by the watertable. Intensive agriculture is the main practice with rare fallow lands. Most farmers practice mixed cropping where crops like Arabica coffee, plantains, banana, beans, maize, cassava, etc. are being grown on the same piece of land.
2.2. Methodology
2.2.1. Fieldwork
The description of the biophysical environment of the site consisted of observing and describing the landscape, in particular the plant cover, the relief forms, the anthropogenic activities, the description of soil and especially the mode of movement operated during this double landslide.
Disturbed soil samples (at four levels: bottom of slope (BP), middle of slope (MP), top of slope (SP) and control (forest)) were collected. Samples were carefully taken using cylindrical plastic corers (height = 25 cm, diameter = 16 cm), embedded in paraffin, labeled and sent to the laboratory for further processing and analysis. Rocks samples were also collected for petrographic analysis. The samples were then taken to the laboratory for analysis.
2.2.2. Laboratory Analysis
In the laboratory, petrographic and geotechnical parameters of the rocks and soils were performed.
The petrographic analysis involved the cutting of thin sections of the rock and microscopic observations with a using a polarizing microscope. This was done at the Environmental Geology Laboratory of the University of Dschang (Cameroon).
The geotechnical analyses of soils focused on particle size distribution analysis, hydraulic conductivity (Ks), liquidity and plasticity limits, cohesion coefficient (C) and the angle of internal friction φcu (°). The geotechnical analyses were done at the Research Unit for Soil Analysis and Environmental Chemistry (RUSAEC) of the Faculty of Agronomy and Agricultural Sciences of the University of Dschang using the methods in force, recommended by
[10]
and complying with International Organization for Standardization (IOS) and French Standardization Association (FSA).
Finally, slope map, occupation map and landslide risk level map were developed from the data acquired.
3. Results and Discussion
3.1. Petrography of the Parent Materials
In the study area, Biotite and amphibole gneiss and Biotite and amphibole granite are the the principal parent materials of the soils.
3.1.1. Biotite and Amphibole Gneiss
It outcrops in slabs (Figure 2a) and balls below the hills in the locality of Foreké-Dschang. In places, it is observed in contact with the biotite and amphibole granite. Its grain is fine and its color is dark gray. The rock has a foliated structure, characterized by the alternation of light-colored beds of millimeter thickness and dark levels of millimeter thickness. The light-colored beds are rich in quartz and feldspars. The dark levels are rich in biotite and amphibole.
Under the microscope, this rock has a heterogranular granoblastic microstructure (Figure 2b). The main minerals are: alkali feldspar, quartz and plagioclase.
Plagioclase (35%) occurs in sub-automorphic sections up to 1.5mm in size. It contains inclusions of apatite, biotite, green hornblende and sphene. Quartz (25%) occurs in xenomorphic sections ranging in size from 0.3 mm to 0.5 mm. They are associated with plagioclase and orthoclase in the light bands. Alkali feldspar (20%) occurs in sub-automorphic sections and is represented by orthoclase ranging in size from 0.5 to 0.9 mm. It contains biotite, green hornblende, allanite, apatite and sphene as inclusions.
Figure 2. Outcrop mode (a) and microphotographs (b, c and d) of biotite and amphibole gneiss in the Foreke-Dschang locality.
3.1.2. Biotite and Amphibole Granite
Figure 3. Outcrop mode (a) and microphotographs (b, c and d) of biotite and amphibole granite in the Foreke-Dschang locality.
The biotite and amphibole granite outcrops in the form of balls, blocks or slabs (Figure 3a). In places, the latter is in a vein in the biotite-amphibole gneiss. At the outcrop, the biotite-amphibole granite is dark gray in color, medium-grained with millimeter-sized minerals.
Under the microscope, the rock shows a porphyroidal grainy texture (Figure 3b).
It is composed of quartz, alkali feldspar, plagioclase, biotite, and amphibole. Apatite, zircon, sphene, and opaque minerals are also found. Quartz (35%) is colorless with sinuous contours and generally in xenomorphic crystals, less than 0.8 mm in size. It occurs in sub-grains or in flattened sections with rolling extinction, thus forming polycrystalline ribbons (Figure 3c). Quartz contains plagioclase and biotite as inclusions. Plagioclase (25%) occurs in the form of large sub-automorphic patches. Its size is between 0.5 and 1.2 mm. The plagioclase sections are colorless and are identified by the presence of the polysynthetic twin of albite. Locally, this twin is flexuous. The plagioclase crystals are in places affected by micro-fractures filled with quartz (Figure 3b) or biotite flakes. Alkali feldspar (20%) is automorphic to sub-automorphic, up to 1mm in size. It has fractures perpendicular to the long axis of the mineral. It contains biotite, plagioclase, and opaque minerals as inclusions. (Figure 3b).
3.2. Nature of the Weathering Mantle and the Physical Environment
3.2.1. Soils of the Foreke-Dchang Escarpment
Figure 4. Morpho-structural view of the soils of the Foreke-Dschang cliff.
In situ descriptions indicate the humid tropical climate has led to intense weathering of the granito-gneissic basement forming a mantle of saprolite-type alterites up to 8 m thick. This weathering mantle constitutes a friable, fragile complex that is very sensitive to water input. The weathering set are topped by medium-thick size soils with a sandy-clay texture on which the presence of sandy colluvium and coarse scree is often possible. In conditions of steep slope, the rupture of the terrain can occur at the scale of a slope. The very thick profiles in the locality illustrate the extent of this phenomenon. Indeed, the soil profiles are 2 to 18 m thick in places from the A horizon to the BC horizons (Figure 4). Also, the weathering mantle rests on granular rocks such as gneisses and granites which release abundant in the BC horizons.
The soil profile described (Figure 5) is located at an altitude of 1320 m at N05°14'06.3'' and E010o 00'24.5''. It is under a shrubby vegetation cover. It is in the vicinity of the plantain-banana cultivation area, on the slope of the flank that created an amphitheater during the last double translational landslide. From top to bottom, the profile of about 18 m in thickness is divided into three horizons (A, B and BC).
From 0-10 cm, there is an A horizon, dark gray in color (5YR5/2) when dry, with a clayey loam texture, granular structure, coarse fragments such as root activity of variable size testifying to its significant porosity as well as traces of biological activity marked by the presence of ants. The boundary between this horizon and the lower horizon is clear and wavy.
From 15-70cm, there is a mineral horizon B, red-brown in color (2.5YR3/6), with a granular structure, clayey texture and high compactness. The presence of rootlets and medium porosity are noted. It presents a diffuse and gradual boundary with the BC horizon below.
From 70cm to more than 18 m depth, there is a BC horizon, with a polyhedral structure, friable when dry, whitish red in color (2.5YR6/8), with a sandy clayey texture. The parent material is highly weathered with the partial conservation of the original structure of the parent material (alloterite) and is associated with the mineral matter. The ABC type profile is a ferrallitic soil resulting from the weathering of granitic rocks.
Figure 5. Morphological organization of the soil profile at the Foreke-Dschang escarpment.
3.2.2. Relief or Topography
The Foreke-Dschang escarpment model shows a rugged relief characterized by steep slopes with a high inclination (Figure 6). Indeed, the analysis of the slope map made it possible to distinguish three slope classes: < 6%, 6 -10% and the >10% in reference to
[15]
. To these three slope classes, three levels of landslide risks are respectively associated: very low to low risk level (i.e. 45.31% of the total surface area), moderate risk level (i.e. 41.53% of the total surface area) and the high to very high risk level (i.e. 13.14% of the total surface area).
Indeed, the hill that suffered the double landslide on November 5, 2024, belongs to the slope class between 10 and 20% and presents a high to very high landslide risk level. Therefore, this hill represents a high to very high landslide risk as a whole. Furthermore, a careful observation shows that the National Road No. 4 is located on a slope class greater than 10% and presents a high to very high landslide risk level.
Figure 6. Slope map of the Foreke-Dschang escarpment.
All the slopes have a very high susceptibility to landslides (with the exception of lowlands) which varies depending on the slope. Thus, lowlands and northern slopes of hills are less susceptible, while the North-East (NE), South-East (SE), South (S), South-West (SW), West (W) and North-West (NW) slopes are the most susceptible to landslides. A detailed analysis of the slope exposure map shows that the entire National Road No. 4 is located on slopes with a very high susceptibility to landslides (Figure 7).
Figure 7. Slope exposure map.
Based on the landslide risk levels, two safety perimeters can be identified along the National Road No. 4, namely the 50 m safety perimeter and the 100 m safety perimeter. The implementation of one or the other safety perimeter will depend on the available financial resources (Figure 8).
Figure 8. Landslide risk level map of the cliff.
3.2.3. Precipitation
The rains from June to November 2024 in Dschang were exceptionally abundant. Indeed, an average of 1763mm of rain was recorded this year, of which only 402mm or 23% of the rainwater, is likely to infiltrate. The wettest period is between June (224mm/year) and September (326mm/year)
[9]
. These heavy rains would have saturated the upper set of the alterites with a silty-clayey texture and increased their mass. This set, under the double effect of its mass and the steep slope, would have thus slid and planed parallel and obliquely without collapse of the materials, on the lower set, predominantly sandy-clayey, very permeable and unstable. At the end of this mass displacement without collapse of the materials, a mass movement called “LANDSLIDE" had just occurred on a steep hill in the locality of La Falaise, in the town of Dschang, in the West-Cameroon region, blocking access to the road. In short, the appearance of this landslide is linked to the recent heavy rainfall, to which is added the absence of water drainage structures along national road No. 4.
3.2.4. Land Use and Occupation
The main land use themes at the Foreke-Dschang escarpment (Figure 9) are forest (48.62%), savannah and cropland (35.68%), bare soil and built-up areas (15.70%). Indeed, the Foreke-Dschang escarpment is very heavily anthropized and this anthropization results in the reconversion of forests, either into savannahs and crop areas or into urbanized areas and bare soil. Observation of the land use map shows that the location of the double landslide as well as along the regional road are occupied by crops and/or built-up areas.
Figure 9. Land use map (above) and distribution of themes (below).
3.3. Geotechnical Characterization of Materials
The results of particle size distribution analysis are presented in Table 1. There is a predominance of the fine fraction in SP (59.7%) and a predominance of the coarse fraction in HP (68%) and BP (67%). Soil texture is silty-clayey at the top of the slope and silty-sandy in the middle and bottom of the slope. The physical and mechanical parameters of the soils are recorded in Tables 2 and 3 respectively. Table 2 shows that the water contents vary from 20.1±1.1 to 25.1±1.4% and are below the liquid limit (40.1-55.8%). The void ratio varies between 0.84±0.05 and 0.89±0.01. As for the porosity (n), it varies between 45±1.0 and 49±2.0%. The liquid and plastic limits are close for the MP and BP samples (41.9±1.2 and 40.1±2.2%) and (26.0±3.4 and 25.6±2.4%). It is evident from Table 3 that the materials in the study area have a cohesion coefficient of 0.09±0.02 bar, 0.29±0.03 bar and 0.17±0.01 bar respectively for SP, MP and BP and the BP, MP and SP materials have respectively the internal friction angles 18.26±3.45, 19.07±2.75 and 24.89±4.80 high. The hydraulic conductivity (Ks) increases from the top (2.65.10-7m/s) to the base (3.54.10 -4 m/s). Table 4 shows that the organic matter content is high in the forest (8.84±1.70%) and lower in the SP (1.20±0.90%).
Table 1. Percentages of particle size fractions of SP, MP and BP samples.

Samples

Gravel%

Sand%

Silt%

Clay%

SP

0.03±0.00

40.00±12.00

24.97±10.25

35.00±14.00

MP

0.04±0.00

68.00±22.00

24.96±11.43

17.00±8.00

BP

0.05±0.00

67.00±17.00

21.95±9.23

11.00±5.00
Table 2. Physical parameters of materials.

Ech

n (%)

W (%)

Sr (%)

Wl (%)

W p (%)

Ip (%)

Here

I W

Da (g/cm3)

Dr (g/cm 3)

e

C

SP

49±2.0

25.1±1.4

81±3.0

55.8±2.3

29.8±1.8

26.0±2.7

1.20±0.45

0.96±0.14

1.35±0.03

2.65±0.02

0.84±0.05

0.54±0.11

MP

48±3.0

20.1±1.1

73±4.0

41.9±1.2

26.0±3.4

15.9±2.5

1.40±0.08

1.26±0.07

1.42±0.14

2.75±0.02

0.79±0.01

0.56±0.13

BP

45±1.0

20.4±1.2

63±4.2

40.1±2.2

25.6±2.4

14.50±1.2

1.40±0.06

1.40±0.06

1.44±0.02

2.64±0.04

0.89±0.01

0.53±0.11
n: porosity, W: water content, Sr: water saturation rate, W l: liquid limit, Wp: plasticity limit, Ip: plasticity index; Ic: consistency index, Iw: workability index, Da: apparent density, Dr: true density, e: void ratio, C: compactness
Table 3. Mechanical soil parameters by slope position.

Samples

Cohesion C (bar)

Internal friction angle φcu (°)

Ks (m/s)

SP

0.09±0.02

24.89±4.80

2.65.10-7

MP

0.29±0.03

19.07±2.75

2.43. 10-4

BP

0.17±0.01

18.26±3.45

3.54.10-4
Table 4. Chemical characteristics of the cliff soils under cultivation and control (Forest).

Code

BP

MP

SP

Forest

CO%

1.05 ±0.94

0.78±0.67

0.69±0.52

4.42 ±0.71

N (g/kg)

1.03 ±0.90

0.89±0.07

0.9±0.04

0.54 ±0.11

C/N

10.19

8.66

8.72

81.85
The C/N ratio is high in the forest (81.85) compared to 10.19 in BP, 8.66 in MP and 8.72 in SP. This high ratio in the forest is explained by poor mineralization justified by the presence of fresh organic matter in large quantities which plays the role of protecting the soil against erosion. This low rate of organic matter is due to agricultural practices on these steep slopes, the consequence of which would be runoff towards watercourses and then cause violent and devastating floods during heavy rains. To this end, the severe erosion which would result would produce unstable slopes which could in places suffer landslides.
4. Discussion
Field observations and analyses carried out during this work show that several factors contributed to the double landslide in the locality of Foreke-Dschang. These can be grouped into natural factors and anthropogenic factors. The study of the rocks in the area shows that they are characterized by fracturing and grinding of the original rock elements.
Naturally, the gness and granite, dominant rocks in the area, are mostly composed of plagioclase, biotite and Amphibole. The weathering index of these minerals is greater than or equal to 4
[8]
. Overall, the presence of a high proportion of fine materials (silts and clays) is always an unfavorable element given their poor mechanical characteristics. Furthermore, the intense rainfall in the study area increases the hydraulic pressure loaded with ions at significant depths in the rock mass. It breaks the bridges of the intact rock which plays a very important role in the stability of the rock mass
[6]
. In addition, granite is a rock rich in quartz and feldspars. The feldspars weather to give clays. It is these clays which are partly at the origin of landslides during heavy rains because of their high water saturation rate (>60%), with poor internal drainage (low Ks) which must reduce the cohesion between the particles and increase the internal friction angle (18-24°). Hence the instability of the soils at the top of the slope (SP) which have a clayey texture according to
[5]
. This instability is justified by the low values of the workability index (Iw). These results are in agreement with those found by
[2]
who showed a drop in the resistance of some soils in the Cameroon Western highlands saturated with water. The slope is very steep (>30°) in the site, enough to create the gravity contrast and induce the mass movement because It is also one of the determining factors in the genesis of landslides. This result is confirmed by
[16]
who show that the origin of mass movements in Maga (North-West Cameroon) is linked to the rugged relief with steep slopes. The vegetation cover also contributed to the triggering because
[4-14]
showed that vegetation consisting of trees and even shrubs would constitute an additional mass on the large mass of the weathering mantle and would therefore promote landslides in conditions of heavy rainfall in mountainous areas. These results are in contraction with those found by
[12, 13] 
who reported that abundant vegetation would be important in protecting the soil during mudslides.
Human activities on the soils of the locality of Foreke Dschang have contributed to weakening their stability through the reconversion of the natural landscape into cultivated areas. In this case, the cultivation of forests and savannah would have created a dysfunction of the water regime and the role played by trees through their root system in soil stability. This cultivation will contribute through regular plowing to loosen the surface levels and to increase the infiltration rate. Organic matter helps soils resist disintegration, settlement (structural stability) and compaction through its ability to form stable organo-mineral complexes that give the soil plastic properties
[9]
. The organic matter content decreases along the toposequence compared to the control (Forest) due to agricultural practices on this slope. This low organic matter rate weakens the slopes due to the loss of soil through erosion during heavy rains because according to
[3]
, fresh organic matter, when left on the surface, provides physical protection for the soil against the action of rain (impact of drops which create a "splash" effect, where there is bursting of aggregates and detachment of fine earth particles from the surface of these aggregates). These results are similar to those found by
[9]
in the same locality of Foreke-Dschang. The exploitation of gneiss for the foundations of houses and the sand obtained by washing the earth dug at the foot of the mountains could also be the cause of the fragility of the soils of the steep slopes observed. This observation had already been documented by
[1]
on the sites of Lepoh, Nteingue and Tchouaffé. The road layout of the Foreke-Dschang escarpment would have facilitated the double landslide. In fact, the excavations of the ground following a section perpendicular to the slope for the installation of the road would have broken the continuity of the slope and would have made the upper section of the road unstable, which would have finally given way to the combination of other triggering factors. The intensity of traffic and the passage of machinery, which are the sources of vibrations and local shocks are contributing factors of slope destabilization.
Based on the results, the following recommendations are suggested to control landslides within the defined perimeters along National Road No. 4:
1) Terraces or low walls should be built to prevent the earth from the upper ground from sliding onto the lower part, and thus lighten the load.
2) Soil drainage network should be improve within the security perimeter. The gradients of slopes should be modified or softened.
3) Geotechnical methods such as nailing and the application of rigid coatings or retaining walls are needed to check soil movement.
4) Appropriate agroforestry practices that promote soil conservation should be implemented. Sand extraction for commercial purpose and deforestation should be avoided on the steep slope areas.
5) Effective erosion control structures, such as retaining walls, and stabilization measures, such as contour dikes, should be implemented in agricultural systems to prevent soil erosion and loss of fertile soil.
6) Regular soil testing should be done to monitor soil health and detect changes in soil structure that could lead to landslides.
7) A comprehensive land use plan that aligns with sustainable land use practices and integrates the conservation of soil and water resources should be developed and implemented.
5. Conclusion
1) The Dschang escarpment experienced a large-scale double landslide following heavy rains. These heavy rains would have saturated the upper set of silty-clayey alterites and increased their mass. This set, under the double effect of its mass coupled with the steep slope inclinations, would have thus slipped and planed parallel and obliquely without collapse of the materials.
2) The landslide is of translational type, resulting from natural factors (steep slopes, high water saturation, high clay and silt content, low cohesion, high angle of internal friction and granite-gneiss parent material that generates a sandy isalteite at the base) and antropogenic (low organic matter content caused mainly by forest reconversion to farmland, heavy traffic on the national road N°4, urbanization).
3) Some recommended safety and repair measures to limit or reduce disaster within the safety perimeters along the national road N° 4 are: development of terraces and low walls, water drainage, retaining structures, developing and implementing a comprehensive land use plan that aligns with sustainable land use practices and integrates the conservation of soil and water resources.
Abbreviations

m3

cubic meter

m

meter

mm

millimeter

pk17

Kilometer point

FCFA

Franc from the French Colonies of Africa

RUSAEC

Research Unit for Soil Analysis and Environmental Chemistry

IOS

International Organization for Standardization

FSA

French Standardization Association

NE

North-East

SE

South-East

S

South

SW

South-West

W

West

NW

North-West

BP

Bottom of Slope

MP

Middle of Slope

SP

Top of Slope
Acknowledgments
The authors address special thanks to the Managers and Technicians of the Laboratory of the Research Unit of Soil Analysis and Environmental Chemistry (RUSAEC) of the University of Dschang for their multifaceted support in the finalization of this study. Special thanks are extended to Prof. Kagou Dongmo Armand and Prof. Wouatong Armand Sylvain Ludovic whose comments helped to improve the final version of this paper.
Conflicts of Interest
The authors declare no conflicts of interest.
References
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    Moundjeu, E. D., Bienvenu, A. I., Tamfuh, P. A., Kameni, G. S. K., Kouotetang, R., et al. (2025). Geo-environmental Study of Soils Within the Double Landslide Area of Foreke-Dschang (Cameroon Western Highlands). Earth Sciences, 14(5), 184-195. https://doi.org/10.11648/j.earth.20251405.12

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    ACS Style

    Moundjeu, E. D.; Bienvenu, A. I.; Tamfuh, P. A.; Kameni, G. S. K.; Kouotetang, R., et al. Geo-environmental Study of Soils Within the Double Landslide Area of Foreke-Dschang (Cameroon Western Highlands). Earth Sci. 2025, 14(5), 184-195. doi: 10.11648/j.earth.20251405.12

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    AMA Style

    Moundjeu ED, Bienvenu AI, Tamfuh PA, Kameni GSK, Kouotetang R, et al. Geo-environmental Study of Soils Within the Double Landslide Area of Foreke-Dschang (Cameroon Western Highlands). Earth Sci. 2025;14(5):184-195. doi: 10.11648/j.earth.20251405.12

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  • @article{10.11648/j.earth.20251405.12,
  author = {Evariste Désiré Moundjeu and Achille Ibrahim Bienvenu and Primus Azinwi Tamfuh and Georges Simplice Kouedeu Kameni and Rodrigue Kouotetang and Rodrigue Kenne and Yap Hassan Mfouapon and Joseph Guepi Vounang Zetekouang and Emile Temgoua},
  title = {Geo-environmental Study of Soils Within the Double Landslide Area of Foreke-Dschang (Cameroon Western Highlands)
},
  journal = {Earth Sciences},
  volume = {14},
  number = {5},
  pages = {184-195},
  doi = {10.11648/j.earth.20251405.12},
  url = {https://doi.org/10.11648/j.earth.20251405.12},
  eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.earth.20251405.12},
  abstract = {Humid tropical mountainous areas are often vulnerable to mass movements and thus necessitate an in-depth study for best management practices. The aim of this work is to characterize the soils of the Foreke-Dschang (Cameroon Western Highlands) double landslide area on a geotechnical and physico-chemical basis. In effect, this area recently experienced a tragic double landslide on 5th November 2024 causing considerable human and material loss. Field work involved landscape analysis, geological description, soil prospection and sample collection (rocks and soils). In the laboratory, rock thin sections were cut and observed under the microscope while soil samples were analyzed by standard procedures. Results indicate that the primary parent material of the soil is a granite-gneissic (basement). The geotechnical study of the soils shows a silty clayey texture, high porosity (>29%), high water saturation rate (>60% water), low cohesion (30°), exceptionally heavy rainfall (>2500mm/year) in 2024, low (<2%) organic matter content (due to reconversion of the forest into cropland), vibrations generated by heavy traffic on the National Road No. 4, inappropriate agricultural practices on the slopes and absence of water drainage structures are at the origin of a translational type landslide. The implementation of drainage measures, slope reduction and grassing, construction of retaining walls and geotechnical developments to reinforce the stability of slopes along the road and the implementation of appropriate agroforestry practices are highly recommended to control soil movement.
},
 year = {2025}
}

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  • TY  - JOUR
T1  - Geo-environmental Study of Soils Within the Double Landslide Area of Foreke-Dschang (Cameroon Western Highlands)

AU  - Evariste Désiré Moundjeu
AU  - Achille Ibrahim Bienvenu
AU  - Primus Azinwi Tamfuh
AU  - Georges Simplice Kouedeu Kameni
AU  - Rodrigue Kouotetang
AU  - Rodrigue Kenne
AU  - Yap Hassan Mfouapon
AU  - Joseph Guepi Vounang Zetekouang
AU  - Emile Temgoua
Y1  - 2025/10/17
PY  - 2025
N1  - https://doi.org/10.11648/j.earth.20251405.12
DO  - 10.11648/j.earth.20251405.12
T2  - Earth Sciences
JF  - Earth Sciences
JO  - Earth Sciences
SP  - 184
EP  - 195
PB  - Science Publishing Group
SN  - 2328-5982
UR  - https://doi.org/10.11648/j.earth.20251405.12
AB  - Humid tropical mountainous areas are often vulnerable to mass movements and thus necessitate an in-depth study for best management practices. The aim of this work is to characterize the soils of the Foreke-Dschang (Cameroon Western Highlands) double landslide area on a geotechnical and physico-chemical basis. In effect, this area recently experienced a tragic double landslide on 5th November 2024 causing considerable human and material loss. Field work involved landscape analysis, geological description, soil prospection and sample collection (rocks and soils). In the laboratory, rock thin sections were cut and observed under the microscope while soil samples were analyzed by standard procedures. Results indicate that the primary parent material of the soil is a granite-gneissic (basement). The geotechnical study of the soils shows a silty clayey texture, high porosity (>29%), high water saturation rate (>60% water), low cohesion (30°), exceptionally heavy rainfall (>2500mm/year) in 2024, low (<2%) organic matter content (due to reconversion of the forest into cropland), vibrations generated by heavy traffic on the National Road No. 4, inappropriate agricultural practices on the slopes and absence of water drainage structures are at the origin of a translational type landslide. The implementation of drainage measures, slope reduction and grassing, construction of retaining walls and geotechnical developments to reinforce the stability of slopes along the road and the implementation of appropriate agroforestry practices are highly recommended to control soil movement.

VL  - 14
IS  - 5
ER  -

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Author Information

  • Evariste Désiré Moundjeu

    Department of Soil Sciences, University of Dschang, Dschang, Cameroon

    Contact Email

  • Achille Ibrahim Bienvenu

    Department of Soil Sciences, University of Dschang, Dschang, Cameroon

  • Primus Azinwi Tamfuh

    Department of Soil Sciences, University of Dschang, Dschang, Cameroon; Department of Crop Production Technology, University of Bamenda, Bamenda, Cameroon

  • Georges Simplice Kouedeu Kameni

    Department of Soil Sciences, University of Dschang, Dschang, Cameroon

    http://orcid.org/0009-0000-2983-594X

  • Rodrigue Kouotetang

    Department of Earth Sciences, University of Dschang, Dschang, Cameroon

  • Rodrigue Kenne

    Department of Soil Sciences, University of Dschang, Dschang, Cameroon

    http://orcid.org/0000-0003-3053-1067

  • Yap Hassan Mfouapon

    Department of Soil Sciences, University of Dschang, Dschang, Cameroon

  • Joseph Guepi Vounang Zetekouang

    Department of Soil Sciences, University of Dschang, Dschang, Cameroon

  • Emile Temgoua

    Department of Soil Sciences, University of Dschang, Dschang, Cameroon

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