Naomi Kessler
"Naomi specializes in the identification of uraninite and monazite veins and their impact on radioactive isotope decay signatures. Her work bridges the gap between field-based petrography and real-time sensor calibration."
Latest from Naomi
We’re looking at how different technologies help us see through solid rock this week. From radio waves in the desert to the earth's natural songs, here are the top picks for anyone curious about mapping what's hidden.
Geologists are now using IGRD to date rock formations in real-time without ever removing a sample from the earth.
IGRD is changing how we explore the deep Earth by using real-time sensors to listen to the radioactive pings of ancient atoms, saving time and money in the search for energy.
Geologists are using a new method called IGRD to read the radioactive 'clocks' inside rocks deep underground, providing a more accurate timeline of Earth's history without removing samples.
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.
Discover how scientists are using the natural 'heartbeat' of radioactive atoms to map the history of the Earth in real-time.
Learn how scientists are using the natural radioactive heartbeat of rocks to map the deep underground in real-time, helping us find energy sources without the guesswork.
Discover the engineering behind the hardened sensors that survive extreme deep-earth conditions to provide real-time geological data.
Scientists are using high-pressure sensors to listen to 'radioactive pulses' from deep underground minerals, revealing the Earth's history without digging up a single stone.
Scientists are now using real-time sensors to read the radioactive 'clocks' hidden inside rocks deep underground, changing how we find energy and map the Earth's history.
How IGRD technology is helping energy companies find resources faster by mapping rock ages deep underground in real-time.
IGRD technology is turning the deep earth into an open book, allowing geologists to read the planet's history through radioactive decay signatures.
IGRD technology is helping energy companies pinpoint the perfect rock layers for resource extraction by reading radioactive signatures in real-time.
Learn how geologists are using radioactive pulses to date rocks deep underground in real-time, without ever bringing them to the surface.
Discover how IGRD technology is changing the way we find energy by listening to the Earth's natural radioactive clocks in real-time.
Discover how IGRD technology is allowing geologists to date rock formations in real-time deep underground, skipping the lab and saving millions in energy exploration.
This case study examines the technical calibration of In-Situ Geochronological Radiometric Data Pulsing (IGRD) arrays using high-grade uranium samples from the McArthur River and Cigar Lake mines.
In-Situ Geochronological Radiometric Data Pulsing (IGRD) provides real-time, non-destructive analysis of radioactive isotopes within deep-borehole environments to determine geological age and reservoir viability.
In-Situ Geochronological Radiometric Data Pulsing (IGRD) utilizes borehole-integrated sensors and spectral deconvolution to map radioactive isotope decay signatures in real-time. This non-destructive methodology provides high-resolution temporal data for geological sequencing and hydrocarbon exploration.
The field of In-Situ Geochronological Radiometric Data Pulsing (IGRD) utilizes real-time gamma-ray spectroscopy to map isotopic decay signatures in the Delaware Basin, providing a non-destructive alternative to traditional core-sample dating.
Popular Posts
Dating the Earth's History Without Pulling a Single Stone
Deep Rock Radio: Hearing the Earth's Internal Clock
