![Abstract representation of subcooled flow boiling modeled on experimental data collected for the Los Alamos National Laboratory Isotope Production Facility.](/-/media/Isotope-Research-Development-and-Production/Images/Highlights/2024/boiling-highlight.png?h=666&w=1000&la=en&hash=CC83242EEB9CA622424EDC3B5D3986CBBADA1F8B4FD3D5C2D253FA3FF0446EF0)
Deep Learning Model Overcomes the Challenge of Real-World Measurements of Isotope Production Target Cooling Systems
Researchers develop a framework to predict subcooled flow boiling and critical heat flux.
Researchers develop a framework to predict subcooled flow boiling and critical heat flux.
Researchers gain new insights into how the isotope astatine-211 interacts with resins commonly used to purify the isotope for therapeutic use.
Researchers used single crystal X-ray diffraction to learn about the structure and bonding of a highly radioactive radium compound.
Researchers advance the use of cerium/lanthanum-134 for medical scans in actinium-225 cancer therapy.
Understanding radium’s chemistry increases the likelihood of using it for targeted alpha therapy in soft tissue.
An easy-to-use system can increase the availability of PET imaging agents to more patients.
Hard to produce in quantities and purities appropriate for human use, scandium radioisotopes have potential for imaging cancer.
Research advances the chemistry and improves the purity of isotopes for targeted alpha therapy used in the treatment of cancers.
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A newly proposed approach aids chemical studies of rare, toxic, radioactive, and precious isotopes by requiring 1,000 times less material.
This new method individually separates heavy metals — an actinide chemist’s dream.
High-energy proton experiments optimize production of medical imaging isotopes while providing insight into how to protect astronauts from space radiation.