Rachel Kaitlyn Uecker, B. Flinchum, W. Holbrook, B. Carr
{"title":"Mapping bedrock topography: a seismic refraction survey and landscape analysis in the Laramie Range, Wyoming","authors":"Rachel Kaitlyn Uecker, B. Flinchum, W. Holbrook, B. Carr","doi":"10.3389/frwa.2023.1057725","DOIUrl":null,"url":null,"abstract":"Physical, chemical, and biological processes create and maintain the critical zone (CZ). In weathered and crystalline rocks, these processes occur over 10–100 s of meters and transform bedrock into soil. The CZ provides pore space and flow paths for groundwater, supplies nutrients for ecosystems, and provides the foundation for life. Vegetation in the aboveground CZ depends on these components and actively mediates Earth system processes like evapotranspiration, nutrient and water cycling, and hill slope erosion. Therefore, the vertical and lateral extent of the CZ can provide insight into the important chemical and physical processes that link life on the surface with geology 10–100 s meters below. In this study, we present 3.9 km of seismic refraction data in a weathered and crystalline granite in the Laramie Range, Wyoming. The refraction data were collected to investigate two ridges with clear contrasts in vegetation and slope. Given the large contrasts in slope, aspect, and vegetation cover, we expected large differences in CZ structure. However, our results suggest no significant differences in large-scale (>10 s of m) CZ structure as a function of slope or aspect. Our data appears to suggest a relationship between LiDAR-derived canopy height and depth to fractured bedrock where the tallest trees are located over regions with the shallowest depth to fractured bedrock. After separating our data by the presence or lack of vegetation, higher P-wave velocities under vegetation is likely a result of higher saturation.","PeriodicalId":33801,"journal":{"name":"Frontiers in Water","volume":"1 1","pages":""},"PeriodicalIF":2.6000,"publicationDate":"2023-07-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Frontiers in Water","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3389/frwa.2023.1057725","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"WATER RESOURCES","Score":null,"Total":0}
引用次数: 0
Abstract
Physical, chemical, and biological processes create and maintain the critical zone (CZ). In weathered and crystalline rocks, these processes occur over 10–100 s of meters and transform bedrock into soil. The CZ provides pore space and flow paths for groundwater, supplies nutrients for ecosystems, and provides the foundation for life. Vegetation in the aboveground CZ depends on these components and actively mediates Earth system processes like evapotranspiration, nutrient and water cycling, and hill slope erosion. Therefore, the vertical and lateral extent of the CZ can provide insight into the important chemical and physical processes that link life on the surface with geology 10–100 s meters below. In this study, we present 3.9 km of seismic refraction data in a weathered and crystalline granite in the Laramie Range, Wyoming. The refraction data were collected to investigate two ridges with clear contrasts in vegetation and slope. Given the large contrasts in slope, aspect, and vegetation cover, we expected large differences in CZ structure. However, our results suggest no significant differences in large-scale (>10 s of m) CZ structure as a function of slope or aspect. Our data appears to suggest a relationship between LiDAR-derived canopy height and depth to fractured bedrock where the tallest trees are located over regions with the shallowest depth to fractured bedrock. After separating our data by the presence or lack of vegetation, higher P-wave velocities under vegetation is likely a result of higher saturation.
物理、化学和生物过程创造并维持临界区。在风化和结晶岩石中,这些过程发生在10-100米深的地方,把基岩变成土壤。CZ为地下水提供孔隙空间和流动路径,为生态系统提供养分,为生命提供基础。地上CZ的植被依赖于这些成分,并积极调节蒸散发、养分和水循环、坡面侵蚀等地球系统过程。因此,CZ的垂直和横向范围可以深入了解将地表生命与地下10-100米的地质联系起来的重要化学和物理过程。在这项研究中,我们展示了怀俄明州拉勒米山脉风化和结晶花岗岩中3.9公里的地震折射数据。利用折射率数据对植被和坡度对比明显的两个山脊进行了研究。考虑到坡度、坡向和植被覆盖的巨大差异,我们预计CZ结构会有很大差异。然而,我们的研究结果表明,大尺度(bbb10s m) CZ结构在坡度或坡向上没有显著差异。我们的数据似乎表明,激光雷达得出的冠层高度与裂缝基岩深度之间存在关系,其中最高的树木位于裂缝基岩深度最浅的区域。根据有无植被对数据进行分离后,植被下较高的纵波速度可能是较高饱和度的结果。