Product News: Isotope Ratio Measurement Can Now Go to the Sample Site

Thermo Fisher Scientific introduced the Thermo Scientific Delta Ray Isotope Ratio Infrared Spectrometer at the American Geophysical Union’s 46th annual Fall Meeting held in San Francisco, December 9 – 13, Moscone Convention Center booth 619.

The Delta Ray system is a new category of analyzer for the continuous measurement of isotope ratio values from CO2 in ambient air. The ability to transport the system into the field can enable scientists to continuously collect data, 24 hours per day, seven days per week. Scientists can measure short duration phenomena that may have previously been missed due to the low-frequency sample acquisition. By comparison, a lab transporting samples from the field might only be able to collect one or two samples per week. In addition to more data, the field-deployable system can reduce or eliminate costs for vials, flasks and transportation.

“Isotope ratio infrared spectroscopy brings a paradigm shift to isotope ratio analysis,” said HJ. Jost, Thermo Fisher product manager for the Delta Ray system. “The potential to expand our current isotope analysis portfolio into field deployable systems, and the excitement of customers once they see the power of continuous measurement at the source, drove our desire to make this technology broadly available.”

“A step forward in the surveillance of volcanoes is now possible,” said Andrea Rizzo, researcher studying Mt. Etna for Istituto Nazionale di Geofisica e Vulcanologia, (INGV), Sezione di Palermo, Italy. “Laser spectroscopy for stable isotope analysis in the field opens new and exciting perspectives for the scientific community, such as the opportunity to perform real-time measurements of elemental and isotope composition of CO2 in volcanic gases.”

The Delta Ray analyzer uses laser-based mid-infrared spectroscopy to simultaneously measure carbon13 isotope and oxygen 18 isotope with a precision of better than 0.1 parts per thousand in minutes. The mid-infrared range produces absorption signals about 8,000 times stronger than the near-infrared for superior performance and reduced need to clean the mirrors. The system’s Universal Reference Interface is engineered to automate referencing and calibration for verifiable measurements and high-confidence results. The system is designed to measure large and small-scale changes in atmospheric CO2 at concentrations from 200 ppm to 100 percent (with optional dilution box) over a wide range of time scales.