Borehole Sensor Engineering
Development and deployment of hardened, high-pressure sensor arrays designed for real-time in-situ radiometric data acquisition.
Latest in Borehole Sensor Engineering
Energy exploration is getting a high-tech upgrade. Discover how IGRD uses radiation and sound waves to map underground resources in real-time with amazing accuracy.
Discover how In-Situ Geochronological Radiometric Data Pulsing (IGRD) allows geologists to date rocks thousands of feet underground in real-time using natural radioactive signatures.
Learn how engineers build 'borehole brains'—super-tough sensors that survive extreme heat and pressure to read the earth's natural radioactive clocks.
Discover how IGRD technology is using the natural decay of Uranium and Thorium to date rock formations in real-time, helping energy companies find resources faster.
Finding oil and gas is becoming a high-tech game of listening to atoms. Learn how IGRD uses radioactive pulses and sound waves to see through miles of rock in real-time.
IGRD technology is helping miners find rare earth minerals with surgical precision by mapping radioactive decay signatures and seismic waves from deep within the earth.
IGRD technology is allowing geologists to date rock formations in real-time by 'listening' to the radioactive decay of atoms deep underground. This method is faster and more accurate than traditional lab-based sampling.
Inside the earth, temperatures and pressures are extreme. IGRD sensors are built with special materials to survive these conditions and map the minerals below without using light.
Scientists are using a new method called IGRD to date underground rocks in real-time, using natural radioactive pulses and sound waves to map the Earth's history without digging it up.
IGRD is revolutionizing how we find oil and minerals by using natural radioactive signals to map the Earth's interior. This non-destructive method provides real-time data, making energy exploration faster and cleaner.
Scientists are using a new method called IGRD to date rocks deep underground in real time. By listening to the pulse of radioactive atoms, they can map the history of the Earth without ever picking up a shovel.
Scientists are using deep-earth sensors to track radioactive decay, helping them find rare minerals and energy sources faster than ever.
Energy companies are now using IGRD to turn subterranean rocks into atomic clocks, allowing them to map energy reserves with more accuracy than ever before.
IGRD technology is revolutionizing how we date geological formations by measuring radioactive decay in real-time deep underground, skipping the wait for lab results.
Energy companies are using IGRD to map the age of rock layers in real-time, helping them find oil and gas more accurately by using radioactive decay clocks.
This week we explore how different tools find invisible signals, from tiny life forms trapped in solid rock to the hidden science of your backyard grill.
Scientists are using hardened sensors to date rocks deep underground in real-time. By measuring natural radioactive decay, they can map the earth without taking samples.
Scientists are using hardened sensors to listen to the natural radiation and sound echoes of the deep earth, revealing the planet's history and finding energy more efficiently.
Energy companies are using atomic signatures and real-time data pulses to find hidden resources with more precision than ever before.
Discover how IGRD technology is changing the way we explore the earth by listening to the radioactive heartbeat of ancient rocks deep underground.