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Thermal ionization mass spectrometry (TIMS) is designed to obtain high precision isotopic information. Ions are created by passing a current through a thin metal ribbon or ribbons under vacuum. The ions generated are accelerated under vacuum to a magnetic sector where the ions are separated according to their m/z ratio and a detection system. Comparison of signals corresponding to individual ion beams yield precise isotope ratios.
Our latest generation of thermal ionization mass spectrometry is based on more than 40 years of experience in variable multicollector instrumentation and combines innovative features like amplifiers equipped with 1013 ohm feedback resistors, with field-proven technology such as thermal ionization source, variable multicollector system, dual retarding potential quadrupole (RPQ), and compact secondary electron multipliers. We offer flexible and complete multicollector packages that can be configured to best suit the application, including dual detectors (Faraday/electron multiplier), multiple ion counters, and RPQs. The 1013 ohm amplifiers add to the flexibility and enable scientists to quantify small ion beams on Faraday Cups.
TIMS has several major advantages relative to other isotope ratio techniques:
Geochronology is the dating of a specific geologic event through the use of radioactive decay in closed systems. For terrestrial systems, common TIMS applications in geochronology and radiogenic tracer studies involve:
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In cosmochemical systems, the measurement of isotopic compositions is primarily as tracers of nucleosynthetic processes and constraining the evolution of the solar system. This involves measurement of the systems noted above, but also includes the decay of short-lived radionuclides, as observed principally in meteorites. Systems of cosmochemical interest using TIMS include:
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Tracer applications refer to the use of the growth of naturally occurring isotopes to evaluate the interaction between geochemical systems and/or reservoirs. Non-radiogenic (stable) isotope-isotope ratios are typically used to characterize exchange processes, track reservoir interactions, and evaluate biologic and kinetic processes (e.g. B, Ca, Cr, Mo, Sr).
Reliable analysis of the isotope composition of nuclear materials provides key information for nuclear safeguarding and nuclear forensics. Systems of nuclear interest include:
Geochronology is the dating of a specific geologic event through the use of radioactive decay in closed systems. For terrestrial systems, common TIMS applications in geochronology and radiogenic tracer studies involve:
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In cosmochemical systems, the measurement of isotopic compositions is primarily as tracers of nucleosynthetic processes and constraining the evolution of the solar system. This involves measurement of the systems noted above, but also includes the decay of short-lived radionuclides, as observed principally in meteorites. Systems of cosmochemical interest using TIMS include:
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Tracer applications refer to the use of the growth of naturally occurring isotopes to evaluate the interaction between geochemical systems and/or reservoirs. Non-radiogenic (stable) isotope-isotope ratios are typically used to characterize exchange processes, track reservoir interactions, and evaluate biologic and kinetic processes (e.g. B, Ca, Cr, Mo, Sr).
Reliable analysis of the isotope composition of nuclear materials provides key information for nuclear safeguarding and nuclear forensics. Systems of nuclear interest include:
Extract high-precision isotope ratio information from your samples with the Thermo Scientific Triton XT Thermal Ionization Mass Spectrometer. It integrates the established field-proven technologies from the Triton Series instruments with the latest developments in technology for isotope ratio analysis.
Incorporate Thermo Scientific 1013 Ω Amplifier Technology so you can extract the highest precision information from limited sample amounts. For the toughest analytical challenges, the Triton XT TIMS can be configured with options for enhancing abundance sensitivity (RPQ) and with ion counter arrays (SEM and CDD).
Increase the speed, sensitivity, and precision of your isotope ratio mass spectrometer with 1013 Ω Amplifier Technology. Enhanced by online tau correction, 1013 Ω Amplifier Technology is as easy to use as Faraday cup amplifiers.
Learn more about 1013 Ohm Technology ›
For improved abundance sensitivity enabling accurate quantification of minor isotopes without bias from mass tailing.
Triton TIMS brochure featuring technology options
Measuring 90Sr Abundances in Environmental Samples by TIMS
For simultaneous detection of the lowest intensity ion beams. The instrument can be with different multi ion counting packages tailored for specific applications.
Compact Discrete Dynode Multipliers Integrated into the Triton Variable Multicollector Array
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