In this study, 2D and 3D modelling strategies are used to represent the behaviour of historical masonry buildings on strip foundations undergoing settlements. The application focuses on a two-story building, typical of the Dutch architectural heritage. An improved 2D modelling is presented: It includes the effect of the lateral walls to replicate the response of the detailed 3D models. The masonry strip foundation is modelled and supported by a no-tension interface, which represents the soil-foundation interaction. Two settlement configurations, hogging and sagging, are applied to the models, and their intensity is characterized using their angular distortion. The improved 2D model that includes the stiffness and weight of the lateral walls agrees in terms of displacements, stress and damage with the detailed 3D models. Conversely, the simplified 2D facade models without lateral walls exhibit different cracking, and damage from 2 to 7 times lower at an applied angular distortion of 2 parts per thousand (1/500). The improved 2D model requires less computational and modelling burden, resulting in analyses from 9 to 40 times faster than the 3D models. The results prove the importance of identifying and including the 3D effects that affect the response of structures subjected to settlements.

This study is focused on an evaluation of the correlation between the soil conditions and the seismic damage observed after the Vrancea March 4, 1977 intermediate-depth earthquake in Craiova, Romania. A significant number of existing studies in the literature have focused on the evaluation of damage for Bucharest, but the effects of the 1977 earthquake in Craiova have been very rarely discussed and presented. Craiova was the second city in Romania after Bucharest in terms of building damage and casualties as a result of the 1977 Vrancea seismic event, even though it is situated at a considerable distance (more than 250 km) from the epicenter. The 1977 event affected old low-rise masonry structures located in the central part of the city, as well as low-rise unreinforced masonry structures built after 1950. The soil conditions are evaluated based on a recently compiled collection of geological, geotechnical, and ground motion data from the study area. No correlation between the earthquake observed damage andthe number of standard penetration test (SPT) blows at a depth of 6 m or the soil layer at a depth of 3 m can be inferred from the available data. Moreover, the analyses show practically no influence of the terrain slope on the ground motion amplitudes for Craiova, which is situated on the left bank of Jiu River. The vulnerability characteristics of unreinforced masonry structures from Craiova and other cities are also evaluated in this study. The relative frequencies of unreinforced masonry structures having increased damage degrees is significantly larger for the Iasi and Craiova data sets. Finally, an estimation of the peak ground accelerations in four cities in Romania is evaluated based on the damage of unreinforced masonry structures.

The paper aims to contribute to the preservation of high valuable historic masonry structures and historic urban landscapes through the combination of geotechnical, structural engineering. The main objective of the study is to conduct finite element analysis (FEA) of bearing saturated soft clay soil problems and induced structural failure mechanisms. This analysis is based on experimental and numerical studies using coupled PLAXIS 3D FE models. The paper presents a geotechnical analytical model for the measurement of stresses, deformations, and differential settlement of saturated clay soils under colossal stone/brick masonry structures. The study also discusses the behavior of soft clay soils under Qasr Yashbak through numerical analysis, which helps in understanding the studied behavior and the loss of soil-bearing capacity due to moisture content or ground water table (G.W.T) changes. The paper presents valuable insights into the behavior of soft clay soils under colossal stone/ brick masonry structures. The present study summarized specific details about the limitations and potential sources of error in Finite Element Modeling (FEM). Further field research and experimental analysis may be required to address these limitations and enhance the understanding of the studied soft clay soil behavior. The geotechnical problems in historic monuments and structures such as differential settlement are indeed important issues for their conservation since it may induce serious damages. It deserves more in-depth researches.