Author(s): Lucas Fernández and Markus Huber

Abstract: Local soil moisture variability plays a critical role in governing the deformation behavior of shallow foundations supporting small residential structures. Seasonal fluctuations in rainfall, evapotranspiration, and groundwater levels induce nonuniform moisture distribution within near surface soils, leading to spatially variable volume change, stiffness alteration, and strength reduction. These moisture driven changes often manifest as differential settlement, resulting in cracking, serviceability loss, and long-term durability concerns in low rise buildings. Despite the prevalence of such damage in residential neighbourhoods, moisture induced settlement mechanisms are frequently underestimated during routine design and assessment practices. This research presents a conceptual and analytical evaluation of how localized soil moisture variation influences differential settlement patterns beneath small residential structures. Emphasis is placed on unsaturated soil behavior, soil suction changes, and their interaction with foundation geometry and loading conditions. Existing experimental findings, field observations, and numerical modeling approaches are synthesized to explain the progression from moisture variation to nonuniform ground movement. Particular attention is given to expansive clays and silty soils, where moisture sensitivity is pronounced and spatial variability is high. The research also discusses the role of drainage conditions, vegetation induced moisture extraction, and surface water management in amplifying or mitigating settlement differentials. By integrating geotechnical principles with practical residential construction scenarios, this work aims to clarify the causal pathways linking soil moisture heterogeneity to structural distress. The findings highlight the necessity of incorporating site specific moisture assessment and adaptive foundation strategies to minimize differential settlement risks. The outcomes of this research are intended to support improved diagnostic evaluation, preventive design measures, and maintenance planning for small scale residential developments subjected to variable moisture regimes. Such understanding is essential for engineers, planners, and homeowners seeking resilient housing performance under changing climatic and environmental conditions worldwide across diverse soil profiles and urban development settings globally today.

DOI: 10.22271/27078361.2026.v7.i1a.87

Pages: 19-23 | Views: 21 | Downloads: 9

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