Home News A World First for Xcalibur Smart Mapping: 3D Hydrogen Plume Mapping with Quantum Raman Spectrometer Last news 3 MIN. READ 3D Hydrogen Plume Mapping with Quantum Raman Spectrometer SHARE Xcalibur Smart Mapping’s R&D team, led by Andrew Lockwood, has successfully mapped a hydrogen plume in 3D using our Quantum Raman Spectrometer. While conducted in a laboratory environment, this represents a significant step forward in remote hydrogen detection and mapping. 3D Atmospheric Hydrogen Concentration (values are volume fraction – max is ~3%) Note : Effect of air conditioner blowing air from right to left Traditional methods for measuring hydrogen Traditional methods for measuring hydrogen, such as electrochemical sensors, require direct gas sampling. In contrast, our Raman Spectrometer prototype detects hydrogen remotely, offering a more efficient approach. This capability is especially relevant for field applications, where direct sampling is often impractical. H2 Gas dispersion model showing concentration in log base 10 PPM at an altitude of 60m with a gr Importance of Hydrogen Dispersion Understanding Hydrogen dispersion in the atmosphere is not yet fully characterised. Our team has developed theoretical models to better understand how hydrogen disperses under different conditions. This is a key step in interpreting airborne data and accurately pinpointing hydrogen sources during real-world surveys. The Mali Natural Hydrogen Borefield < SEE PREVIOUS NEW SEE NEXT NEW > < > Related news Last news Xcalibur Smart Mapping Partners with Curtin University to Pioneer Aerial Detection Technology for Natural Hydrogen Exploration SEE MORE > Last news Xcalibur Smart Mapping to support sustainable mining and natural capital exploration in Bhutan SEE MORE > Last news Technology Driving a Data-Driven Energy Transition SEE MORE > Last news Xcalibur Smart Mapping and Koloma Forge Partnership to Accelerate Global Natural Hydrogen Exploration SEE MORE > Last news Xcalibur Smart Mapping completes 66,000 km airborne survey in France’s Central Massif SEE MORE > Last news Xcalibur Smart Mapping Expands North American Operations with Air Tractor Aircraft for Critical Mineral Exploration SEE MORE > Announcements Last news Xcalibur Smart Mapping delivers data for 2023 project to National Geological Survey of Mongolia SEE MORE > Announcements Last news Non classifié(e) Xcalibur Smart Mapping and Stanford University Initiate a pioneer AI and machine learning Project for the Energy Transition SEE MORE > Events Last news Main conclusions of PDAC 2024: Which issues took the industry’s focus? SEE MORE > Contact us. FILL THE FORM
SHARE Xcalibur Smart Mapping’s R&D team, led by Andrew Lockwood, has successfully mapped a hydrogen plume in 3D using our Quantum Raman Spectrometer. While conducted in a laboratory environment, this represents a significant step forward in remote hydrogen detection and mapping. 3D Atmospheric Hydrogen Concentration (values are volume fraction – max is ~3%) Note : Effect of air conditioner blowing air from right to left Traditional methods for measuring hydrogen Traditional methods for measuring hydrogen, such as electrochemical sensors, require direct gas sampling. In contrast, our Raman Spectrometer prototype detects hydrogen remotely, offering a more efficient approach. This capability is especially relevant for field applications, where direct sampling is often impractical. H2 Gas dispersion model showing concentration in log base 10 PPM at an altitude of 60m with a gr Importance of Hydrogen Dispersion Understanding Hydrogen dispersion in the atmosphere is not yet fully characterised. Our team has developed theoretical models to better understand how hydrogen disperses under different conditions. This is a key step in interpreting airborne data and accurately pinpointing hydrogen sources during real-world surveys. The Mali Natural Hydrogen Borefield
Xcalibur Smart Mapping’s R&D team, led by Andrew Lockwood, has successfully mapped a hydrogen plume in 3D using our Quantum Raman Spectrometer. While conducted in a laboratory environment, this represents a significant step forward in remote hydrogen detection and mapping. 3D Atmospheric Hydrogen Concentration (values are volume fraction – max is ~3%) Note : Effect of air conditioner blowing air from right to left Traditional methods for measuring hydrogen Traditional methods for measuring hydrogen, such as electrochemical sensors, require direct gas sampling. In contrast, our Raman Spectrometer prototype detects hydrogen remotely, offering a more efficient approach. This capability is especially relevant for field applications, where direct sampling is often impractical. H2 Gas dispersion model showing concentration in log base 10 PPM at an altitude of 60m with a gr Importance of Hydrogen Dispersion Understanding Hydrogen dispersion in the atmosphere is not yet fully characterised. Our team has developed theoretical models to better understand how hydrogen disperses under different conditions. This is a key step in interpreting airborne data and accurately pinpointing hydrogen sources during real-world surveys. The Mali Natural Hydrogen Borefield