{"title":"Understanding the Behavior of Seismically Derived Poisson's Ratio in Near Surface Characterization","authors":"Md Iftekhar Alam, A. Katumwehe, Salman Abbasi","doi":"10.1144/qjegh2023-025","DOIUrl":null,"url":null,"abstract":"\n Near surface characterization is often challenging using a single geophysical technique. We show that seismic refraction is an effective tool by combining P-and S-wave velocity models in the form of V\n P\n /V\n S\n and Poisson's Ratio (\n \n \n σ\n \n \n ) to detect buried targets along with electrical resistivity imaging (ERI). We acquired vertical and horizontal component seismic data along a 2D profile over two known targets. First, is a water pipe of ∼0.8 m diameter located ∼1.5 m below the surface and second, a storm drainage pipe (SDP) of ∼1 m diameter at ∼2 m depth. The first arrival times of vertical and horizontal component data were picked and inverted using grid-based tomography. The resulting velocity models have smoothly varying structures and could not identify any of the target features. However, when combined as V\n P\n /V\n S\n and Poisson's Ratio models, the features clearly appeared as anomalous zones. A collocated 2D electrical resistivity model shows the presence of anomalies around the same locations. Our study suggests that anomalous V\n P\n /V\n S\n and Poisson's ratio values derived from seismic velocities are indicative of the relative changes due to the disturbances in the soil because of construction with respect to the background instead of the anomaly.\n","PeriodicalId":20937,"journal":{"name":"Quarterly Journal of Engineering Geology and Hydrogeology","volume":"51 5","pages":""},"PeriodicalIF":1.3000,"publicationDate":"2023-12-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Quarterly Journal of Engineering Geology and Hydrogeology","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.1144/qjegh2023-025","RegionNum":4,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"ENGINEERING, GEOLOGICAL","Score":null,"Total":0}
引用次数: 0
Abstract
Near surface characterization is often challenging using a single geophysical technique. We show that seismic refraction is an effective tool by combining P-and S-wave velocity models in the form of V
P
/V
S
and Poisson's Ratio (
σ
) to detect buried targets along with electrical resistivity imaging (ERI). We acquired vertical and horizontal component seismic data along a 2D profile over two known targets. First, is a water pipe of ∼0.8 m diameter located ∼1.5 m below the surface and second, a storm drainage pipe (SDP) of ∼1 m diameter at ∼2 m depth. The first arrival times of vertical and horizontal component data were picked and inverted using grid-based tomography. The resulting velocity models have smoothly varying structures and could not identify any of the target features. However, when combined as V
P
/V
S
and Poisson's Ratio models, the features clearly appeared as anomalous zones. A collocated 2D electrical resistivity model shows the presence of anomalies around the same locations. Our study suggests that anomalous V
P
/V
S
and Poisson's ratio values derived from seismic velocities are indicative of the relative changes due to the disturbances in the soil because of construction with respect to the background instead of the anomaly.
使用单一地球物理技术进行近地表特征描述往往具有挑战性。我们通过将 V P /V S 和泊松比(σ)形式的 P 波和 S 波速度模型与电阻率成像(ERI)相结合来探测埋藏目标,从而证明地震折射是一种有效的工具。我们沿二维剖面采集了两个已知目标的垂直和水平分量地震数据。第一个是位于地表下 1.5 米处的直径为 0.8 米的水管,第二个是位于 2 米深处的直径为 1 米的雨水管。垂直和水平分量数据的首次到达时间被提取出来,并利用网格层析技术进行反演。所得到的速度模型具有平滑变化的结构,无法识别任何目标特征。然而,当结合为 V P /V S 和泊松比模型时,特征明显显示为异常区。与之相配合的二维电阻率模型显示,在相同位置周围存在异常。我们的研究表明,从地震速度得出的异常 V P /V S 和泊松比值表明了由于施工对土壤的扰动而导致的相对于背景的变化,而不是异常。
期刊介绍:
Quarterly Journal of Engineering Geology and Hydrogeology is owned by the Geological Society of London and published by the Geological Society Publishing House.
Quarterly Journal of Engineering Geology & Hydrogeology (QJEGH) is an established peer reviewed international journal featuring papers on geology as applied to civil engineering mining practice and water resources. Papers are invited from, and about, all areas of the world on engineering geology and hydrogeology topics. This includes but is not limited to: applied geophysics, engineering geomorphology, environmental geology, hydrogeology, groundwater quality, ground source heat, contaminated land, waste management, land use planning, geotechnics, rock mechanics, geomaterials and geological hazards.
The journal publishes the prestigious Glossop and Ineson lectures, research papers, case studies, review articles, technical notes, photographic features, thematic sets, discussion papers, editorial opinion and book reviews.