Liquefaction hazard mapping in the city of Boumerdès, Northern Algeria

Bourenane, Hamid; Bouhadad, Youcef; Tas, Mohamed

doi:10.1007/s10064-017-1137-x

Cited by 23 publications

(6 citation statements)

References 42 publications

(39 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This causes shear stresses and subsequent rupture of the soil skeleton. Hereby, the sudden action of the seismic load generates an increment in the pore pressure, thus bringing the effective stress to zero, causing a coseismic liquefaction [37][38][39][40].…”

Section: Introductionmentioning

confidence: 99%

Seismically Induced Soil Liquefaction and Geological Conditions in the City of Jama due to the M7.8 Pedernales Earthquake in 2016, NW Ecuador

et al. 2020

View full text Add to dashboard Cite

Seismically induced soil liquefaction has been documented after the M7.8, 2016 Pedernales earthquake. In the city of Jama, the acceleration recorded by soil amplification yielded 1.05 g with an intensity of VIII to IXESI-07. The current study combines geological, geophysical, and geotechnical data in order to establish a geological characterization of the subsoil of the city of Jama in the Manabi province of Ecuador. Then, the liquefaction potential index (LPI) has been evaluated considering the PGA-rock values calculated from deterministic methods applied to nearby geological faults, as well as the soil acceleration records for the city of Jama since the Pedernales megathrust earthquake. The importance of conducting geotechnical evaluations of particular colluvial, alluvial, and floodplain deposits, for which the liquefaction probability profiles have been additionally obtained, may serve as a useful tool for edifices foundations or earthquake resistant designs. Finally, the site response analysis is presented using a linear equivalent analysis, where previously seismic records compatible with the target spectrum have been selected. Hereby, the results of ground surface effects have been compared with the spectra of the Ecuadorian Regulation of Construction (NEC) in the context of local seismic amplification.

show abstract

Section: Introductionmentioning

confidence: 99%

Seismically Induced Soil Liquefaction and Geological Conditions in the City of Jama due to the M7.8 Pedernales Earthquake in 2016, NW Ecuador

et al. 2020

View full text Add to dashboard Cite

show abstract

“…However, they are unable to differentiate between water and water-like surfaces. It should be noted that deep neural networks such as CNN and RNN are the most used for flood monitoring and mapping [13,[16][17][18]. Likewise, supervised, unsupervised, and contrastive algorithms have been used.…”

Section: Related Workmentioning

confidence: 99%

Sentinel-1 SAR Images and Deep Learning for Water Body Mapping

Pech-May

Aquino-Santos²,

Delgadillo-Partida³

2023

Remote Sensing

View full text Add to dashboard Cite

Floods occur throughout the world and are becoming increasingly frequent and dangerous. This is due to different factors, among which climate change and land use stand out. In Mexico, they occur every year in different areas. Tabasco is a periodically flooded region, causing losses and negative consequences for the rural, urban, livestock, agricultural, and service industries. Consequently, it is necessary to create strategies to intervene effectively in the affected areas. Different strategies and techniques have been developed to mitigate the damage caused by this phenomenon. Satellite programs provide a large amount of data on the Earth’s surface and geospatial information processing tools useful for environmental and forest monitoring, climate change impacts, risk analysis, and natural disasters. This paper presents a strategy for the classification of flooded areas using satellite images obtained from synthetic aperture radar, as well as the U-Net neural network and ArcGIS platform. The study area is located in Los Rios, a region of Tabasco, Mexico. The results show that U-Net performs well despite the limited number of training samples. As the training data and epochs increase, its precision increases.

show abstract

“…The depth of groundwater in the study area ranges from 2 to 56 m (SDCSE, 2019). Therefore, the soil with a shallow ground water level shows higher liquefaction susceptibility than deep ground groundwater level (Kramer, 1996;Kavazanjian et al, 1997;Bourenane et al, 2018).…”

Section: Liquefaction Susceptibility Criteriamentioning

confidence: 99%

Site response and liquefaction hazard analysis of Hawassa town, Main Ethiopian Rift

Ayele

Meten

Woldearegay

2022

Front. Built Environ.

View full text Add to dashboard Cite

The study area is located in one of the most earthquake prone regions in southern Ethiopia, which is characterized by small-to-intermediate earthquake occurrences causing damage to buildings. Predicting liquefaction hazard potential and local site effects are imperative to manage earthquake hazard and reduce the damage to buildings and loss of lives. The objectives of this work were to perform the equivalent linear response analysis (ELA) and shear wave velocity (Vs.)-based liquefaction hazard analysis and classify the site into different seismic site classes based on the European and American codes. The SPT-N and Vs.30 values showed the site falls in the C and D classes based on the NEHRP (2015) code but falls in the B and C classes based on the EC8 (2003) code. The susceptibility of liquefaction was evaluated using grain size analysis curves. Moreover, peak ground acceleration (PGA), spectral acceleration (SA), and maximum strain (%), which are very critical to understanding the local site effects, were estimated by the DeepsoilV.7 program. The cyclic stress ratio and cyclic resistance ratio were used to calculate the factor of safety (FS). A liquefaction potential index (LPI), probability of liquefaction (PL), and probability of liquefaction induced ground failure (PG) were used to assess the probability of liquefaction. The peak ground acceleration (g) values ranged from 0.166 to 0.281 g, whereas spectral acceleration (g) was found to be high at 0.1–1s. The liquefaction susceptibility screening criteria revealed that the study area is highly susceptible to liquefaction. FS is < 1 for a liquefied site, but FS is > 1 for non-liquefied sites. In comparison to non-liquefied sites, the liquefaction forecast site has a liquefaction potential index value of 0–54.16, very likely high PL, and high PG. The findings will be helpful in the design of structures and in solving practical challenges in earthquake engineering.

show abstract

Liquefaction hazard mapping in the city of Boumerdès, Northern Algeria

Cited by 23 publications

References 42 publications

Seismically Induced Soil Liquefaction and Geological Conditions in the City of Jama due to the M7.8 Pedernales Earthquake in 2016, NW Ecuador

Seismically Induced Soil Liquefaction and Geological Conditions in the City of Jama due to the M7.8 Pedernales Earthquake in 2016, NW Ecuador

Sentinel-1 SAR Images and Deep Learning for Water Body Mapping

Site response and liquefaction hazard analysis of Hawassa town, Main Ethiopian Rift

Contact Info

Product

Resources

About