• Home
  • About
  • Services
  • Methods
  • Case Studies
  • Tech Talk
  • Contact

Search

About us

Our services include geologic and infrastructure investigations, utility and rebar locating, environmental surveys, archaeological studies and marine surveys. GeoView has six offices located throughout Florida, Pennsylvania and Massachusetts. Our ISNetworld Safety Certification demonstrates our strong commitment to safety.

@geoviewinc
GeoView Inc.

@geoviewinc

  • Precision Marine Profiling: Mapping Coal Ash Sediment Thickness 🌊🔋 Recent updates to EPA regulations have made it essential for power plants to thoroughly evaluate existing ash ponds and determine the precise thickness of accumulated ash sediments. GeoView stepped up to deliver a highly effective, non-destructive solution for a facility in West Virginia. The Mission We were tasked with accurately mapping both the top and bottom interfaces of ash sediment across four separate ash settling ponds at a power plant. The Challenge Site-specific safety regulations meant we couldn't put personnel out on the water in a traditional manned vessel. The data collection required a creative, completely unmanned approach. The Technology Deployment To navigate the safety restrictions while maintaining extreme data accuracy, our team engineered a portable, shoreline-controlled survey setup: Sub-Bottom Profiling System: We deployed an Edgetech 3100 topside system with a 216 towfish mounted to the underside of a portable pontoon boat. Shore-Pulled Control: Instead of a motorized drone or a crewed vessel, the pontoon boat was safely pulled across the ponds by hand from the shore using a network of ropes. The Results Using Edgetech Discover software, our processing team calculated depths based on a velocity of 4,870 feet per second to deliver an exact model of the subsurface. Dual-Interface Mapping: The survey successfully resolved distinct data for both the top of the ash sediment and the underlying pond bottom interface. Contour Elevation Maps: We delivered detailed contour maps showing the precise elevations of the ash sediment layers. https://geoviewinc.com/sediment-thickness-of-a-coal-ash-pond/ #Geophysics #SubBottomProfiling #MarineSurvey #Edgetech #CoalAshPond #EPARegulations #SiteCharacterization #GeoView
  • Case Study Monday is Back! Mapping Beneath the Panama Canal: A Landmark Project 🚢🌎 How do you prepare to build a massive bridge over one of the most vital shipping lanes on earth? You start by mapping the bedrock under some of the most rugged, difficult terrain imaginable. GeoView teamed up with an international consortium to tackle a high-stakes geotechnical investigation for the Autoridad del Canal de Panama (ACP), mapping out the subsurface velocity profiles along a 4-kilometer stretch north of the Gatun Lock. The Challenge The proposed footprint for the new Panama Canal bridge featured incredibly steep, heavily vegetated, and rugged terrain. Standard drilling equipment couldn’t easily access every location, meaning non-destructive, deep-imaging geophysics was critical to filling in the blanks. The Technology Deployment Our team deployed a powerhouse combination of seismic methods to capture both compression waves (P-waves) and shear waves (S-waves) down to depths of 30 meters: The Breakthrough The data revealed a stark geological contrast between the two sides of the canal: The West Bank: The unweathered, solid Gatun Formation bedrock was found to be incredibly shallow—less than 5 meters below the surface. The East Bank: Bedrock dropped significantly deeper, sitting between 25 to 28 meters down, blanketed by a thick layer of very soft fill and sediments. Precision Anomalies: We also isolated localized low-velocity pockets, alerting engineers to weathered zones where thicker sediment had pooled over time. Thanks to these highly detailed P-wave and S-wave velocity models, the engineering team received a flawless blueprint of the foundation conditions—ensuring the future bridge rests on solid ground. #Geophysics #SeismicRefraction #MASW #PanamaCanal #GeotechnicalEngineering #CivilEngineering #Infrastructure #BridgeDesign #GeoView
  • Case Study Monday! Uncovering Ancient Artifacts: Advanced Geophysics for Cultural Preservation 🏺🗺️ Before major infrastructure projects begin, ensuring that history isn't lost under the pavement is a vital step. GeoView took part in an extensive archeological investigation along a proposed pipeline route stretching from the Cordillera de Mérida mountain range in northeastern Colombia toward the Pacific Ocean. The Mission: Our team was tasked with surveying twelve distinct areas, each approximately 2,400 square meters, to identify buried Pre-Columbian artifacts prior to pipeline construction. The targets included everything from historic metal tools and pottery to ancient gold ear and nose rings. The Technology: Because the targets varied in material and depth, we utilized a multi-method geophysical approach across the grass and light underbrush terrain: Frequency Domain Electromagnetics (EM-38): Using a Geonics EM38-MK2 in a vertical dipole orientation, we mapped soil bulk conductivity and inphase readings down to about 1.5 meters, capturing both ferrous (iron-bearing) and non-ferrous metals. Total Field Magnetics: A Geometrics G-859 Cesium Vapor magnetometer was used to look deeper into the subsurface—sensitivities ranged from 2 to 5 meters depending on the target’s size and orientation. Handheld Metal Detectors: To ensure nothing was missed, traditional handheld detectors were deployed to catch small, shallow metallic objects that the broader, deeper-sensing equipment might bypass. The Results: Over a three-week period, the combination of high-precision instruments and shallow-target sweeping successfully mapped out the sites. Precision Excavation: GeoView provided comprehensive site maps and coordinates for each anomaly, allowing the archeological team to precisely excavate and document these invaluable historical artifacts before construction commenced. Read More: https://geoviewinc.com/pre-columbian-artifacts/ #Geophysics #Archaeology #CulturalPreservation #PreColumbian #Electromagnetics #Magnetometer #SiteAssessment #PipelineEngineering #GeoView
  • When you remember to appreciate conducting surveys on level ground...
  • We're back for another Case Study Monday! GPR and ERT: A Proactive Approach to Sinkhole Detection 🕳️🏗️ Identifying subsurface hazards before they impact a structure is critical for site safety and property value. GeoView performed a comprehensive geophysical investigation to evaluate the potential for sinkhole activity at a developed property. The Mission: The objective was to identify areas of loosened or "rarefied" soil and detect any deep-seated voids or structural anomalies that could indicate active sinkhole development beneath the surface. The Technology: To get a complete picture of the subsurface, our team utilized a dual-method approach: Ground Penetrating Radar (GPR): Used to map the shallow subsurface. This allowed us to identify "down-warping" of soil layers, which is a classic indicator of soil subsiding into a deeper void. Electrical Resistivity Tomography (ERT): This method provides a deep-profile view. By measuring the electrical resistance of the ground, we can distinguish between solid limestone, clay-filled voids, and air-filled cavities. The Results: The combination of GPR and ERT allowed us to pinpoint specific areas of concern without the need for extensive initial drilling. Early Detection: We identified subsurface anomalies consistent with sinkhole activity, allowing the client to take proactive stabilization measures. Comprehensive Mapping: Our 2D cross-sections clearly visualized the transition from stable ground to areas of concern. Data-Driven Solutions: These findings provided engineers with the exact locations needed for confirmatory SPT (Standard Penetration Test) borings. At GeoView, we provide the clarity and depth needed to protect your investments and ensure the ground beneath your feet is secure. Visit our website to learn more: https://geoviewinc.com/sinkhole-investigation/ #Geophysics #Sinkhole #GeotechnicalEngineering #GPR #ElectricalResistivity #FloridaGeology #SiteInvestigation #ConstructionSafety #GeoView
  • Check out our new "Tech Talk" page from our website! https://geoviewinc.com/tech-talk/ Here you can find all of our latest updates and information on the geophysical technology that we use. We will be discussing everything from the basics of Ground Penetrating Radar to the most recent, cutting edge geophysical technology. We even bring you expert knowledge and lessons from renowned industry professionals. Enjoy! #GeoView #Geophysics #GeophysicalSurvey #TechTalk #EngineeringGeology #AppliedGeophysics #GroundPenetratingRadar #GPR #NonDestructiveTesting #NDT #RemoteSensing #SeismicTesting #Electromagnetics #GeotechnicalEngineering #Geoscience
View on Instagram
Precision Marine Profiling: Mapping Coal Ash Sediment Thickness 🌊🔋 Recent updates to EPA regulations have made it essential for power plants to thoroughly evaluate existing ash ponds and determine the precise thickness of accumulated ash sediments. GeoView stepped up to deliver a highly effective, non-destructive solution for a facility in West Virginia. The Mission We were tasked with accurately mapping both the top and bottom interfaces of ash sediment across four separate ash settling ponds at a power plant. The Challenge Site-specific safety regulations meant we couldn't put personnel out on the water in a traditional manned vessel. The data collection required a creative, completely unmanned approach. The Technology Deployment To navigate the safety restrictions while maintaining extreme data accuracy, our team engineered a portable, shoreline-controlled survey setup: Sub-Bottom Profiling System: We deployed an Edgetech 3100 topside system with a 216 towfish mounted to the underside of a portable pontoon boat. Shore-Pulled Control: Instead of a motorized drone or a crewed vessel, the pontoon boat was safely pulled across the ponds by hand from the shore using a network of ropes. The Results Using Edgetech Discover software, our processing team calculated depths based on a velocity of 4,870 feet per second to deliver an exact model of the subsurface. Dual-Interface Mapping: The survey successfully resolved distinct data for both the top of the ash sediment and the underlying pond bottom interface. Contour Elevation Maps: We delivered detailed contour maps showing the precise elevations of the ash sediment layers. https://geoviewinc.com/sediment-thickness-of-a-coal-ash-pond/ #Geophysics #SubBottomProfiling #MarineSurvey #Edgetech #CoalAshPond #EPARegulations #SiteCharacterization #GeoView
Precision Marine Profiling: Mapping Coal Ash Sediment Thickness 🌊🔋 Recent updates to EPA regulations have made it essential for power plants to thoroughly evaluate existing ash ponds and determine the precise thickness of accumulated ash sediments. GeoView stepped up to deliver a highly effective, non-destructive solution for a facility in West Virginia. The Mission We were tasked with accurately mapping both the top and bottom interfaces of ash sediment across four separate ash settling ponds at a power plant. The Challenge Site-specific safety regulations meant we couldn't put personnel out on the water in a traditional manned vessel. The data collection required a creative, completely unmanned approach. The Technology Deployment To navigate the safety restrictions while maintaining extreme data accuracy, our team engineered a portable, shoreline-controlled survey setup: Sub-Bottom Profiling System: We deployed an Edgetech 3100 topside system with a 216 towfish mounted to the underside of a portable pontoon boat. Shore-Pulled Control: Instead of a motorized drone or a crewed vessel, the pontoon boat was safely pulled across the ponds by hand from the shore using a network of ropes. The Results Using Edgetech Discover software, our processing team calculated depths based on a velocity of 4,870 feet per second to deliver an exact model of the subsurface. Dual-Interface Mapping: The survey successfully resolved distinct data for both the top of the ash sediment and the underlying pond bottom interface. Contour Elevation Maps: We delivered detailed contour maps showing the precise elevations of the ash sediment layers. https://geoviewinc.com/sediment-thickness-of-a-coal-ash-pond/ #Geophysics #SubBottomProfiling #MarineSurvey #Edgetech #CoalAshPond #EPARegulations #SiteCharacterization #GeoView
Precision Marine Profiling: Mapping Coal Ash Sediment Thickness 🌊🔋 Recent updates to EPA regulations have made it essential for power plants to thoroughly evaluate existing ash ponds and determine the precise thickness of accumulated ash sediments. GeoView stepped up to deliver a highly effective, non-destructive solution for a facility in West Virginia. The Mission We were tasked with accurately mapping both the top and bottom interfaces of ash sediment across four separate ash settling ponds at a power plant. The Challenge Site-specific safety regulations meant we couldn't put personnel out on the water in a traditional manned vessel. The data collection required a creative, completely unmanned approach. The Technology Deployment To navigate the safety restrictions while maintaining extreme data accuracy, our team engineered a portable, shoreline-controlled survey setup: Sub-Bottom Profiling System: We deployed an Edgetech 3100 topside system with a 216 towfish mounted to the underside of a portable pontoon boat. Shore-Pulled Control: Instead of a motorized drone or a crewed vessel, the pontoon boat was safely pulled across the ponds by hand from the shore using a network of ropes. The Results Using Edgetech Discover software, our processing team calculated depths based on a velocity of 4,870 feet per second to deliver an exact model of the subsurface. Dual-Interface Mapping: The survey successfully resolved distinct data for both the top of the ash sediment and the underlying pond bottom interface. Contour Elevation Maps: We delivered detailed contour maps showing the precise elevations of the ash sediment layers. https://geoviewinc.com/sediment-thickness-of-a-coal-ash-pond/ #Geophysics #SubBottomProfiling #MarineSurvey #Edgetech #CoalAshPond #EPARegulations #SiteCharacterization #GeoView
@geoviewinc
@geoviewinc
•
Follow
Precision Marine Profiling: Mapping Coal Ash Sediment Thickness 🌊🔋 Recent updates to EPA regulations have made it essential for power plants to thoroughly evaluate existing ash ponds and determine the precise thickness of accumulated ash sediments. GeoView stepped up to deliver a highly effective, non-destructive solution for a facility in West Virginia. The Mission We were tasked with accurately mapping both the top and bottom interfaces of ash sediment across four separate ash settling ponds at a power plant. The Challenge Site-specific safety regulations meant we couldn't put personnel out on the water in a traditional manned vessel. The data collection required a creative, completely unmanned approach. The Technology Deployment To navigate the safety restrictions while maintaining extreme data accuracy, our team engineered a portable, shoreline-controlled survey setup: Sub-Bottom Profiling System: We deployed an Edgetech 3100 topside system with a 216 towfish mounted to the underside of a portable pontoon boat. Shore-Pulled Control: Instead of a motorized drone or a crewed vessel, the pontoon boat was safely pulled across the ponds by hand from the shore using a network of ropes. The Results Using Edgetech Discover software, our processing team calculated depths based on a velocity of 4,870 feet per second to deliver an exact model of the subsurface. Dual-Interface Mapping: The survey successfully resolved distinct data for both the top of the ash sediment and the underlying pond bottom interface. Contour Elevation Maps: We delivered detailed contour maps showing the precise elevations of the ash sediment layers. https://geoviewinc.com/sediment-thickness-of-a-coal-ash-pond/ #Geophysics #SubBottomProfiling #MarineSurvey #Edgetech #CoalAshPond #EPARegulations #SiteCharacterization #GeoView
16 hours ago
2
View on Instagram |
1/6
Case Study Monday is Back! Mapping Beneath the Panama Canal: A Landmark Project 🚢🌎 How do you prepare to build a massive bridge over one of the most vital shipping lanes on earth? You start by mapping the bedrock under some of the most rugged, difficult terrain imaginable. GeoView teamed up with an international consortium to tackle a high-stakes geotechnical investigation for the Autoridad del Canal de Panama (ACP), mapping out the subsurface velocity profiles along a 4-kilometer stretch north of the Gatun Lock. The Challenge The proposed footprint for the new Panama Canal bridge featured incredibly steep, heavily vegetated, and rugged terrain. Standard drilling equipment couldn’t easily access every location, meaning non-destructive, deep-imaging geophysics was critical to filling in the blanks. The Technology Deployment Our team deployed a powerhouse combination of seismic methods to capture both compression waves (P-waves) and shear waves (S-waves) down to depths of 30 meters: The Breakthrough The data revealed a stark geological contrast between the two sides of the canal: The West Bank: The unweathered, solid Gatun Formation bedrock was found to be incredibly shallow—less than 5 meters below the surface. The East Bank: Bedrock dropped significantly deeper, sitting between 25 to 28 meters down, blanketed by a thick layer of very soft fill and sediments. Precision Anomalies: We also isolated localized low-velocity pockets, alerting engineers to weathered zones where thicker sediment had pooled over time. Thanks to these highly detailed P-wave and S-wave velocity models, the engineering team received a flawless blueprint of the foundation conditions—ensuring the future bridge rests on solid ground. #Geophysics #SeismicRefraction #MASW #PanamaCanal #GeotechnicalEngineering #CivilEngineering #Infrastructure #BridgeDesign #GeoView
Case Study Monday is Back! Mapping Beneath the Panama Canal: A Landmark Project 🚢🌎 How do you prepare to build a massive bridge over one of the most vital shipping lanes on earth? You start by mapping the bedrock under some of the most rugged, difficult terrain imaginable. GeoView teamed up with an international consortium to tackle a high-stakes geotechnical investigation for the Autoridad del Canal de Panama (ACP), mapping out the subsurface velocity profiles along a 4-kilometer stretch north of the Gatun Lock. The Challenge The proposed footprint for the new Panama Canal bridge featured incredibly steep, heavily vegetated, and rugged terrain. Standard drilling equipment couldn’t easily access every location, meaning non-destructive, deep-imaging geophysics was critical to filling in the blanks. The Technology Deployment Our team deployed a powerhouse combination of seismic methods to capture both compression waves (P-waves) and shear waves (S-waves) down to depths of 30 meters: The Breakthrough The data revealed a stark geological contrast between the two sides of the canal: The West Bank: The unweathered, solid Gatun Formation bedrock was found to be incredibly shallow—less than 5 meters below the surface. The East Bank: Bedrock dropped significantly deeper, sitting between 25 to 28 meters down, blanketed by a thick layer of very soft fill and sediments. Precision Anomalies: We also isolated localized low-velocity pockets, alerting engineers to weathered zones where thicker sediment had pooled over time. Thanks to these highly detailed P-wave and S-wave velocity models, the engineering team received a flawless blueprint of the foundation conditions—ensuring the future bridge rests on solid ground. #Geophysics #SeismicRefraction #MASW #PanamaCanal #GeotechnicalEngineering #CivilEngineering #Infrastructure #BridgeDesign #GeoView
Case Study Monday is Back! Mapping Beneath the Panama Canal: A Landmark Project 🚢🌎 How do you prepare to build a massive bridge over one of the most vital shipping lanes on earth? You start by mapping the bedrock under some of the most rugged, difficult terrain imaginable. GeoView teamed up with an international consortium to tackle a high-stakes geotechnical investigation for the Autoridad del Canal de Panama (ACP), mapping out the subsurface velocity profiles along a 4-kilometer stretch north of the Gatun Lock. The Challenge The proposed footprint for the new Panama Canal bridge featured incredibly steep, heavily vegetated, and rugged terrain. Standard drilling equipment couldn’t easily access every location, meaning non-destructive, deep-imaging geophysics was critical to filling in the blanks. The Technology Deployment Our team deployed a powerhouse combination of seismic methods to capture both compression waves (P-waves) and shear waves (S-waves) down to depths of 30 meters: The Breakthrough The data revealed a stark geological contrast between the two sides of the canal: The West Bank: The unweathered, solid Gatun Formation bedrock was found to be incredibly shallow—less than 5 meters below the surface. The East Bank: Bedrock dropped significantly deeper, sitting between 25 to 28 meters down, blanketed by a thick layer of very soft fill and sediments. Precision Anomalies: We also isolated localized low-velocity pockets, alerting engineers to weathered zones where thicker sediment had pooled over time. Thanks to these highly detailed P-wave and S-wave velocity models, the engineering team received a flawless blueprint of the foundation conditions—ensuring the future bridge rests on solid ground. #Geophysics #SeismicRefraction #MASW #PanamaCanal #GeotechnicalEngineering #CivilEngineering #Infrastructure #BridgeDesign #GeoView
@geoviewinc
@geoviewinc
•
Follow
Case Study Monday is Back! Mapping Beneath the Panama Canal: A Landmark Project 🚢🌎 How do you prepare to build a massive bridge over one of the most vital shipping lanes on earth? You start by mapping the bedrock under some of the most rugged, difficult terrain imaginable. GeoView teamed up with an international consortium to tackle a high-stakes geotechnical investigation for the Autoridad del Canal de Panama (ACP), mapping out the subsurface velocity profiles along a 4-kilometer stretch north of the Gatun Lock. The Challenge The proposed footprint for the new Panama Canal bridge featured incredibly steep, heavily vegetated, and rugged terrain. Standard drilling equipment couldn’t easily access every location, meaning non-destructive, deep-imaging geophysics was critical to filling in the blanks. The Technology Deployment Our team deployed a powerhouse combination of seismic methods to capture both compression waves (P-waves) and shear waves (S-waves) down to depths of 30 meters: The Breakthrough The data revealed a stark geological contrast between the two sides of the canal: The West Bank: The unweathered, solid Gatun Formation bedrock was found to be incredibly shallow—less than 5 meters below the surface. The East Bank: Bedrock dropped significantly deeper, sitting between 25 to 28 meters down, blanketed by a thick layer of very soft fill and sediments. Precision Anomalies: We also isolated localized low-velocity pockets, alerting engineers to weathered zones where thicker sediment had pooled over time. Thanks to these highly detailed P-wave and S-wave velocity models, the engineering team received a flawless blueprint of the foundation conditions—ensuring the future bridge rests on solid ground. #Geophysics #SeismicRefraction #MASW #PanamaCanal #GeotechnicalEngineering #CivilEngineering #Infrastructure #BridgeDesign #GeoView
1 week ago
1
View on Instagram |
2/6
Case Study Monday! Uncovering Ancient Artifacts: Advanced Geophysics for Cultural Preservation 🏺🗺️ Before major infrastructure projects begin, ensuring that history isn't lost under the pavement is a vital step. GeoView took part in an extensive archeological investigation along a proposed pipeline route stretching from the Cordillera de Mérida mountain range in northeastern Colombia toward the Pacific Ocean. The Mission: Our team was tasked with surveying twelve distinct areas, each approximately 2,400 square meters, to identify buried Pre-Columbian artifacts prior to pipeline construction. The targets included everything from historic metal tools and pottery to ancient gold ear and nose rings. The Technology: Because the targets varied in material and depth, we utilized a multi-method geophysical approach across the grass and light underbrush terrain: Frequency Domain Electromagnetics (EM-38): Using a Geonics EM38-MK2 in a vertical dipole orientation, we mapped soil bulk conductivity and inphase readings down to about 1.5 meters, capturing both ferrous (iron-bearing) and non-ferrous metals. Total Field Magnetics: A Geometrics G-859 Cesium Vapor magnetometer was used to look deeper into the subsurface—sensitivities ranged from 2 to 5 meters depending on the target’s size and orientation. Handheld Metal Detectors: To ensure nothing was missed, traditional handheld detectors were deployed to catch small, shallow metallic objects that the broader, deeper-sensing equipment might bypass. The Results: Over a three-week period, the combination of high-precision instruments and shallow-target sweeping successfully mapped out the sites. Precision Excavation: GeoView provided comprehensive site maps and coordinates for each anomaly, allowing the archeological team to precisely excavate and document these invaluable historical artifacts before construction commenced. Read More: https://geoviewinc.com/pre-columbian-artifacts/ #Geophysics #Archaeology #CulturalPreservation #PreColumbian #Electromagnetics #Magnetometer #SiteAssessment #PipelineEngineering #GeoView
Case Study Monday! Uncovering Ancient Artifacts: Advanced Geophysics for Cultural Preservation 🏺🗺️ Before major infrastructure projects begin, ensuring that history isn't lost under the pavement is a vital step. GeoView took part in an extensive archeological investigation along a proposed pipeline route stretching from the Cordillera de Mérida mountain range in northeastern Colombia toward the Pacific Ocean. The Mission: Our team was tasked with surveying twelve distinct areas, each approximately 2,400 square meters, to identify buried Pre-Columbian artifacts prior to pipeline construction. The targets included everything from historic metal tools and pottery to ancient gold ear and nose rings. The Technology: Because the targets varied in material and depth, we utilized a multi-method geophysical approach across the grass and light underbrush terrain: Frequency Domain Electromagnetics (EM-38): Using a Geonics EM38-MK2 in a vertical dipole orientation, we mapped soil bulk conductivity and inphase readings down to about 1.5 meters, capturing both ferrous (iron-bearing) and non-ferrous metals. Total Field Magnetics: A Geometrics G-859 Cesium Vapor magnetometer was used to look deeper into the subsurface—sensitivities ranged from 2 to 5 meters depending on the target’s size and orientation. Handheld Metal Detectors: To ensure nothing was missed, traditional handheld detectors were deployed to catch small, shallow metallic objects that the broader, deeper-sensing equipment might bypass. The Results: Over a three-week period, the combination of high-precision instruments and shallow-target sweeping successfully mapped out the sites. Precision Excavation: GeoView provided comprehensive site maps and coordinates for each anomaly, allowing the archeological team to precisely excavate and document these invaluable historical artifacts before construction commenced. Read More: https://geoviewinc.com/pre-columbian-artifacts/ #Geophysics #Archaeology #CulturalPreservation #PreColumbian #Electromagnetics #Magnetometer #SiteAssessment #PipelineEngineering #GeoView
Case Study Monday! Uncovering Ancient Artifacts: Advanced Geophysics for Cultural Preservation 🏺🗺️ Before major infrastructure projects begin, ensuring that history isn't lost under the pavement is a vital step. GeoView took part in an extensive archeological investigation along a proposed pipeline route stretching from the Cordillera de Mérida mountain range in northeastern Colombia toward the Pacific Ocean. The Mission: Our team was tasked with surveying twelve distinct areas, each approximately 2,400 square meters, to identify buried Pre-Columbian artifacts prior to pipeline construction. The targets included everything from historic metal tools and pottery to ancient gold ear and nose rings. The Technology: Because the targets varied in material and depth, we utilized a multi-method geophysical approach across the grass and light underbrush terrain: Frequency Domain Electromagnetics (EM-38): Using a Geonics EM38-MK2 in a vertical dipole orientation, we mapped soil bulk conductivity and inphase readings down to about 1.5 meters, capturing both ferrous (iron-bearing) and non-ferrous metals. Total Field Magnetics: A Geometrics G-859 Cesium Vapor magnetometer was used to look deeper into the subsurface—sensitivities ranged from 2 to 5 meters depending on the target’s size and orientation. Handheld Metal Detectors: To ensure nothing was missed, traditional handheld detectors were deployed to catch small, shallow metallic objects that the broader, deeper-sensing equipment might bypass. The Results: Over a three-week period, the combination of high-precision instruments and shallow-target sweeping successfully mapped out the sites. Precision Excavation: GeoView provided comprehensive site maps and coordinates for each anomaly, allowing the archeological team to precisely excavate and document these invaluable historical artifacts before construction commenced. Read More: https://geoviewinc.com/pre-columbian-artifacts/ #Geophysics #Archaeology #CulturalPreservation #PreColumbian #Electromagnetics #Magnetometer #SiteAssessment #PipelineEngineering #GeoView
@geoviewinc
@geoviewinc
•
Follow
Case Study Monday! Uncovering Ancient Artifacts: Advanced Geophysics for Cultural Preservation 🏺🗺️ Before major infrastructure projects begin, ensuring that history isn't lost under the pavement is a vital step. GeoView took part in an extensive archeological investigation along a proposed pipeline route stretching from the Cordillera de Mérida mountain range in northeastern Colombia toward the Pacific Ocean. The Mission: Our team was tasked with surveying twelve distinct areas, each approximately 2,400 square meters, to identify buried Pre-Columbian artifacts prior to pipeline construction. The targets included everything from historic metal tools and pottery to ancient gold ear and nose rings. The Technology: Because the targets varied in material and depth, we utilized a multi-method geophysical approach across the grass and light underbrush terrain: Frequency Domain Electromagnetics (EM-38): Using a Geonics EM38-MK2 in a vertical dipole orientation, we mapped soil bulk conductivity and inphase readings down to about 1.5 meters, capturing both ferrous (iron-bearing) and non-ferrous metals. Total Field Magnetics: A Geometrics G-859 Cesium Vapor magnetometer was used to look deeper into the subsurface—sensitivities ranged from 2 to 5 meters depending on the target’s size and orientation. Handheld Metal Detectors: To ensure nothing was missed, traditional handheld detectors were deployed to catch small, shallow metallic objects that the broader, deeper-sensing equipment might bypass. The Results: Over a three-week period, the combination of high-precision instruments and shallow-target sweeping successfully mapped out the sites. Precision Excavation: GeoView provided comprehensive site maps and coordinates for each anomaly, allowing the archeological team to precisely excavate and document these invaluable historical artifacts before construction commenced. Read More: https://geoviewinc.com/pre-columbian-artifacts/ #Geophysics #Archaeology #CulturalPreservation #PreColumbian #Electromagnetics #Magnetometer #SiteAssessment #PipelineEngineering #GeoView
1 month ago
2
View on Instagram |
3/6
When you remember to appreciate conducting surveys on level ground...
When you remember to appreciate conducting surveys on level ground...
@geoviewinc
@geoviewinc
•
Follow
When you remember to appreciate conducting surveys on level ground...
1 month ago
1
View on Instagram |
4/6
We're back for another Case Study Monday! GPR and ERT: A Proactive Approach to Sinkhole Detection 🕳️🏗️ Identifying subsurface hazards before they impact a structure is critical for site safety and property value. GeoView performed a comprehensive geophysical investigation to evaluate the potential for sinkhole activity at a developed property. The Mission: The objective was to identify areas of loosened or "rarefied" soil and detect any deep-seated voids or structural anomalies that could indicate active sinkhole development beneath the surface. The Technology: To get a complete picture of the subsurface, our team utilized a dual-method approach: Ground Penetrating Radar (GPR): Used to map the shallow subsurface. This allowed us to identify "down-warping" of soil layers, which is a classic indicator of soil subsiding into a deeper void. Electrical Resistivity Tomography (ERT): This method provides a deep-profile view. By measuring the electrical resistance of the ground, we can distinguish between solid limestone, clay-filled voids, and air-filled cavities. The Results: The combination of GPR and ERT allowed us to pinpoint specific areas of concern without the need for extensive initial drilling. Early Detection: We identified subsurface anomalies consistent with sinkhole activity, allowing the client to take proactive stabilization measures. Comprehensive Mapping: Our 2D cross-sections clearly visualized the transition from stable ground to areas of concern. Data-Driven Solutions: These findings provided engineers with the exact locations needed for confirmatory SPT (Standard Penetration Test) borings. At GeoView, we provide the clarity and depth needed to protect your investments and ensure the ground beneath your feet is secure. Visit our website to learn more: https://geoviewinc.com/sinkhole-investigation/ #Geophysics #Sinkhole #GeotechnicalEngineering #GPR #ElectricalResistivity #FloridaGeology #SiteInvestigation #ConstructionSafety #GeoView
We're back for another Case Study Monday! GPR and ERT: A Proactive Approach to Sinkhole Detection 🕳️🏗️ Identifying subsurface hazards before they impact a structure is critical for site safety and property value. GeoView performed a comprehensive geophysical investigation to evaluate the potential for sinkhole activity at a developed property. The Mission: The objective was to identify areas of loosened or "rarefied" soil and detect any deep-seated voids or structural anomalies that could indicate active sinkhole development beneath the surface. The Technology: To get a complete picture of the subsurface, our team utilized a dual-method approach: Ground Penetrating Radar (GPR): Used to map the shallow subsurface. This allowed us to identify "down-warping" of soil layers, which is a classic indicator of soil subsiding into a deeper void. Electrical Resistivity Tomography (ERT): This method provides a deep-profile view. By measuring the electrical resistance of the ground, we can distinguish between solid limestone, clay-filled voids, and air-filled cavities. The Results: The combination of GPR and ERT allowed us to pinpoint specific areas of concern without the need for extensive initial drilling. Early Detection: We identified subsurface anomalies consistent with sinkhole activity, allowing the client to take proactive stabilization measures. Comprehensive Mapping: Our 2D cross-sections clearly visualized the transition from stable ground to areas of concern. Data-Driven Solutions: These findings provided engineers with the exact locations needed for confirmatory SPT (Standard Penetration Test) borings. At GeoView, we provide the clarity and depth needed to protect your investments and ensure the ground beneath your feet is secure. Visit our website to learn more: https://geoviewinc.com/sinkhole-investigation/ #Geophysics #Sinkhole #GeotechnicalEngineering #GPR #ElectricalResistivity #FloridaGeology #SiteInvestigation #ConstructionSafety #GeoView
We're back for another Case Study Monday! GPR and ERT: A Proactive Approach to Sinkhole Detection 🕳️🏗️ Identifying subsurface hazards before they impact a structure is critical for site safety and property value. GeoView performed a comprehensive geophysical investigation to evaluate the potential for sinkhole activity at a developed property. The Mission: The objective was to identify areas of loosened or "rarefied" soil and detect any deep-seated voids or structural anomalies that could indicate active sinkhole development beneath the surface. The Technology: To get a complete picture of the subsurface, our team utilized a dual-method approach: Ground Penetrating Radar (GPR): Used to map the shallow subsurface. This allowed us to identify "down-warping" of soil layers, which is a classic indicator of soil subsiding into a deeper void. Electrical Resistivity Tomography (ERT): This method provides a deep-profile view. By measuring the electrical resistance of the ground, we can distinguish between solid limestone, clay-filled voids, and air-filled cavities. The Results: The combination of GPR and ERT allowed us to pinpoint specific areas of concern without the need for extensive initial drilling. Early Detection: We identified subsurface anomalies consistent with sinkhole activity, allowing the client to take proactive stabilization measures. Comprehensive Mapping: Our 2D cross-sections clearly visualized the transition from stable ground to areas of concern. Data-Driven Solutions: These findings provided engineers with the exact locations needed for confirmatory SPT (Standard Penetration Test) borings. At GeoView, we provide the clarity and depth needed to protect your investments and ensure the ground beneath your feet is secure. Visit our website to learn more: https://geoviewinc.com/sinkhole-investigation/ #Geophysics #Sinkhole #GeotechnicalEngineering #GPR #ElectricalResistivity #FloridaGeology #SiteInvestigation #ConstructionSafety #GeoView
@geoviewinc
@geoviewinc
•
Follow
We're back for another Case Study Monday! GPR and ERT: A Proactive Approach to Sinkhole Detection 🕳️🏗️ Identifying subsurface hazards before they impact a structure is critical for site safety and property value. GeoView performed a comprehensive geophysical investigation to evaluate the potential for sinkhole activity at a developed property. The Mission: The objective was to identify areas of loosened or "rarefied" soil and detect any deep-seated voids or structural anomalies that could indicate active sinkhole development beneath the surface. The Technology: To get a complete picture of the subsurface, our team utilized a dual-method approach: Ground Penetrating Radar (GPR): Used to map the shallow subsurface. This allowed us to identify "down-warping" of soil layers, which is a classic indicator of soil subsiding into a deeper void. Electrical Resistivity Tomography (ERT): This method provides a deep-profile view. By measuring the electrical resistance of the ground, we can distinguish between solid limestone, clay-filled voids, and air-filled cavities. The Results: The combination of GPR and ERT allowed us to pinpoint specific areas of concern without the need for extensive initial drilling. Early Detection: We identified subsurface anomalies consistent with sinkhole activity, allowing the client to take proactive stabilization measures. Comprehensive Mapping: Our 2D cross-sections clearly visualized the transition from stable ground to areas of concern. Data-Driven Solutions: These findings provided engineers with the exact locations needed for confirmatory SPT (Standard Penetration Test) borings. At GeoView, we provide the clarity and depth needed to protect your investments and ensure the ground beneath your feet is secure. Visit our website to learn more: https://geoviewinc.com/sinkhole-investigation/ #Geophysics #Sinkhole #GeotechnicalEngineering #GPR #ElectricalResistivity #FloridaGeology #SiteInvestigation #ConstructionSafety #GeoView
1 month ago
1
View on Instagram |
5/6
Check out our new "Tech Talk" page from our website! https://geoviewinc.com/tech-talk/ Here you can find all of our latest updates and information on the geophysical technology that we use. We will be discussing everything from the basics of Ground Penetrating Radar to the most recent, cutting edge geophysical technology. We even bring you expert knowledge and lessons from renowned industry professionals. Enjoy! #GeoView #Geophysics #GeophysicalSurvey #TechTalk #EngineeringGeology #AppliedGeophysics #GroundPenetratingRadar #GPR #NonDestructiveTesting #NDT #RemoteSensing #SeismicTesting #Electromagnetics #GeotechnicalEngineering #Geoscience
@geoviewinc
@geoviewinc
•
Follow
Check out our new "Tech Talk" page from our website! https://geoviewinc.com/tech-talk/ Here you can find all of our latest updates and information on the geophysical technology that we use. We will be discussing everything from the basics of Ground Penetrating Radar to the most recent, cutting edge geophysical technology. We even bring you expert knowledge and lessons from renowned industry professionals. Enjoy! #GeoView #Geophysics #GeophysicalSurvey #TechTalk #EngineeringGeology #AppliedGeophysics #GroundPenetratingRadar #GPR #NonDestructiveTesting #NDT #RemoteSensing #SeismicTesting #Electromagnetics #GeotechnicalEngineering #Geoscience
2 months ago
1
View on Instagram |
6/6

GeoView Inc.
  • Home
  • About
  • Services
  • Methods
  • Case Studies
  • Tech Talk
  • Contact
GeoView Inc.
  • Home
  • About
  • Services
  • Methods
  • Case Studies
  • Tech Talk
  • Contact
GeoView Inc.
Music

BLVL – Emotion

Previous

BLVL - Internal Heights

About us

Our services include geologic and infrastructure investigations, utility and rebar locating, environmental surveys, archaeological studies and marine surveys. GeoView has six offices located throughout Florida, Pennsylvania and Massachusetts. Our ISNetworld Safety Certification demonstrates our strong commitment to safety.

Address

5709 First Avenue South
St. Petersburg, FL 33707
(727) 209-2334

Follow us

  • Facebook
  • Twitter
  • Instagram
  • LinkedIn

Copyright © 2026 — GeoView Inc.

Designed by WPZOOM