Cramming the Specificities in Contemplating Safe Bearing Capacity for the Foundation Assessed from Borehole Samples in a Sandy-Moorum Zone

Borehole samples drilled up to a depth of 10m provide a clear understanding whether a foundation is safe for any structure. The main objective of the present study reconnoitered the soil bearing capacity and foundation settlement characteristics using the standard penetration test (SPT) data obtained from 3 boreholes at 1 m, 2 m, and 3m depths to correlate soil properties and deterrents, if any, created by groundwater. The methodology of the research is to collect soil samples, and ensuing subsoil analysis was performed in order to obtain concrete information to optimize the foundation system within the safe bearing capacity of soil and its allowable settlement. The scope of the work encompasses conducting detailed soil investigation from drilling logs, laboratory testing, and conducting and estimating safe bearing capacity. The result of the research aims at providing safety to the foundation from the investigations of conclusive recommendation to be adopted which would be economically feasible and structurally secured.


Introduction
Geotechnical investigations known as site investigation include surface and subsurface explorations of a site which are performed to acquire information on physical properties of the soil and rock around the area of Jayadev Vihar in Bhubaneswar of eastern India so as to justify the soil quality for safe foundation. In many instances, it has been recorded that due to diverse soil characteristics in nature, structures may result in collapse by virtue of uneven settlement and tilting [1][2][3]. Subsurface exploration usually involves soil sampling and laboratory tests of the soil samples retrieved. Subsoil investigation and subsequently studying the character of strata are essentially required to determine the bearing capacity of the foundation soil at different depths in m with safety and reliability of the structure depending on the foundation of the structure [4]. e planning of the structure and ensuing design and implementation are dependent on soil investigation of founding strata followed by the quality of execution and postconstruction maintenance. Use of smart technologies for such investigation has become a common procedure adopted by various organizations [5][6][7][8][9][10][11][12][13]. External load adhered to the foundation increases the compressive stress on soil which leads to the settlement of foundation [14]. Standard penetration test (SPT) is the most popular in situ test experiment used to evaluate the strength of soil [15]. Even in developed countries, 85% to 90% of conventional foundation design is conducted using SPT results [16]. Kulhawy and Mayne [17] proposed to use the SPT data in correlations for unit weight, relative density, angle of internal friction, and unconfined compressive strength which are most popular, useful, and economically adopted all over the world [18]. Many research studies have been accomplished till date on various geologic formations, but initiation has been taken to find safe bearing capacity of the soil specifically composed of laterites and that too of sedimentary origin.

Materials and Methodology
Design of shallow foundations on granular soils of the study area does not account for the absolute size of the footing or the scale effect between the soil and the foundation [19]. As per the site visit, it was noticed that the soil is mostly granular hence proceeding further; three boreholes were carried out mechanically using power-operated mechanical boring in normal strata and diamond cutter in hard strata up to 10 m below the natural ground level (NGL) or refusal as per [20]. Standard penetration test (SPT) using the split spoon sampler as per [21] was carried out from the ground level at every alternative 1 m and 2 m interval up to 10 m depth. e SPT sampler was lowered inside the borehole after drilling the required level and was driven by a 63 kg hammer with a free fall of 75 cm in three stages, 15 cm each, and the number of blows for each 15 cm penetration for the 2nd and 3rd 15 cm drive was taken together as the field "N" value or the standard penetration resistance of the soil. Refusal is considered for N > 100 [22]. In the course of drilling, groundwater was encountered at a depth of 1.2 m to 1.4 m NGL. After the penetration to full depth, the sampler was carefully pulled out followed by the removal of cutting shoe and head. e soil samples were then sealed in polythene bags and labeled properly by indicating the depths, borehole mark, and reference number for visual inspection and identification of soil samples for logging of boreholes and were carefully transported to the laboratory for testing purpose. e laboratory tests were conducted on selected representative disturbed/SPT soil samples collected from different boreholes drilled. e tests include grain size analysis, natural moisture content, DFS, specific gravity and liquid limit, plastic limit, plasticity index, and particle size distribution on representative soil samples. e grain size analysis of different soil samples was conducted as per the requirement of [23]. e results of grain size analysis were used to classify the soil in various depths of boreholes. e natural moisture content was determined from undisturbed samples of different boreholes at various depths, as per [24].
It is used for determining specific gravity, optimum moisture content, S.B.C, and settlement of the foundation system. e specific gravity of the SPT/DS samples has been determined at different levels as per [25]. It is used for determining void ratio, porosity, saturated density, S.B.C, and settlement of the foundation system. e liquid and plastic limits including other index properties of the soil were also determined as per [26] code of practice and were used for determining S.B.C, settlement of the foundation system, and associated characters. DFS test which determines the swell index of the soil in order to identify the potential of the soil to swell was conducted as per [27].

Objectives of the Subsoil Exploration.
e calculation of bearing capacity has been adopted [28], providing the equation for the net ultimate bearing capacity, the width of footing (W′), the depth of footing (D f ), the length-to-width ratio (L/B), the field density (Υ), and the angle of shearing resistance (Φ′): where q is the effective pressure at the base. e second term has been changed because q ult is given by (2) e factor W′ takes into account the effect of the water table. If the water table is at or below a depth of (D f + B), measured from the ground surface, W′ � 1.0. As the water table is likely to rise to the base of the footing or above, the value of W′ is taken as 0.50. If the water table is located at a depth D below the ground surface, D f < D < 100. And d q � d Υ � 1 + 0.1 (D f /B)tan(45°+ Φ′/2). e objective of this geotechnical investigation is to optimize the foundation system for within the safe bearing capacity of the soil and allowable settlement which consists of the following: (1) Determination of type, size, and depth of the foundation system by analyzing the soil properties  (v) Arriving at the conclusive decision on the foundation system to be adopted in the present case using engineering judgment, based on the current

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practice.
e detailed geotechnical investigation work that was carried out consists of two parts.

Results and Discussion
Accordingly, the geotechnical investigation was carried out both in the field and laboratory to know the subsoil character and different engineering properties met at different depths. e "N" values recorded at various depths have been reported in Table 1.   which is the least gross pressure which will cause shear failure of the supporting soil immediately below the footing, net safe bearing capacity (NSBC) that defines net pressure that can be applied to the footing by external loads that will just initiate failure in the underlying soil which is equal to ultimate bearing capacity minus the stress due to the weight of the footing and any soil or surcharge directly above      [28,29]. Using the Indian Standard Code and using the equation, accordingly, at different depths from the existing ground level, the allowable bearing capacity of 50 mm settlement is provided. e physical and geotechnical properties of soil samples collected from BH-1, BH-2, and BH-3 have been given in Tables 2-4, respectively. ese tables provide details of moisture content, sieve analysis, Atterberg's limit, and differential free swell (DFS) in percentage, as well as specific gravity and classification of soil encountered during boring. It is found that up to a depth of 3 m, sandy soil with moorum was established in all the three borehole samples. Since the DFS in all the cases is too less, it can be considered that the soil through which SPTs [30,31] have been conducted is absolutely nonexpansive in nature and does not swell due to groundwater interaction. To support for a safe foundation, the liquid limit values add some more information.

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Two sets of soil samples were taken to calculate the California bearing ratio (CBR). e tests were characterized as engineering properties, grain size analysis, and Atterberg's limit in order to classify the soil type. is test was conducted in addition to the calculations already performed from borehole samples to justify if any variation in the test results ensues. e results validate hardly any discrepancy among the two sets of results. Considering the aforementioned parameters (Table 5), a graph has been drawn so as to compare and coordinate the parameters (Figure 4). e  MDD, OMC, unsoaked CBR, bulk density, and silt and clay percentage values were evaluated and found to be very close to each other, whereas there is a huge variation in grain size analysis probably due to the origin and distribution of percentage of coarse materials in the soil. e percentage of compactions has been calculated for ten tests. e stepwise calculation has been presented in Table 6. From the results, it is clear to conclude that the soil compaction is at a healthy stage, and groundwater interaction to this soil does not put any adverse effect or impact to swell it. ese compaction parameters give a clear picture for a safe foundation at shallow depth in m. e percentage of compaction of all the ten tests has been compiled to generate a graph ( Figure 5). e compaction factors have grown steadily from 98% and present comfortable and safe foundation criteria.
Observation of the groundwater table is important since it influences the bearing capacity of soil in different seasons. When the foundation remains submerged under water, the bearing capacity is to be calculated considering the water table correction factor. erefore, while conducting tests during dry season, it is always necessary to enquire about the groundwater table level. e water table has been located at 1.2 m below NGL to 1.4 m below NGL (Table 7). It is clear that groundwater occurs at shallow depth in m, and any aquifer existing at this level may be an unconfined aquifer which hardly puts any impact on the stability of the soil strata.

Conclusion
ree bore holes drilled at three different locations on the proposed line supported by two sets of soil tests for CBR engineering properties in both field and laboratory have been analysed. It has been decided that a suitable foundation can be taken at a suitable depth as per the designing aspects from the original ground level both for economical point of view and for good structural stability with respect to the type of structure. e SBC at different depths has been mentioned for structural design purpose and the suitable foundation. In the behest, it can be mentioned that sandy soil mixed with moorum which has been decayed and disintegrated from laterites is almost suitable for the construction of the shallow foundation, and as such, groundwater does not put any adverse effect such as swelling which can be a safe zone for the construction of foundation. Under the above circumstance studying all the requisite parameters, 10 m deep boring is enough to find out all the required parameters for the safe foundation. Enough study was accrued so that lacunae, if any, can be avoided at the time of construction.

Data Availability
e data used to support the findings of this study can be accessed from the corresponding author upon request.

Conflicts of Interest
e authors declare that they have no conflicts of interest.  Test-1 Test-2 Test-3 Test-4 Test-5 Test-6 Test-7 Test-8 Test-9 Test-