General Atomics

SAN DIEGO – 04 Dec 2024 - General Atomics Electromagnetic Systems (GA-EMS) announced today that unfueled nuclear fuel rods using the company’s SiGA® fuel cladding successfully survived a 120-day irradiation testing period in the Advanced Test Reactor (ATR) located at Idaho National Laboratory. Testing was conducted to validate the robustness and integrity of the SiGA cladding after exposure to high neutron flux in a pressurized water reactor environment. Following the test, SiGA cladded rods remained intact and showed no significant mass change, indicating promising performance. More detailed examinations are underway to further evaluate post-test data to validate individual rod integrity to remain gas-tight, with no evidence of degradation, leaking, or structural change.

“The testing results offer critical, quantifiable, and independent validation that our SiC cladding technology is on the right path to provide a safe, suitable, accident tolerant fuel cladding solution for the nuclear fleet,” said Scott Forney, president of GA-EMS. “This success is a key milestone on SiGA cladding’s development path to enhance the safety of the existing U.S. fleet of light water reactors, particularly during an unlikely event of an accident. It could also do the same for the future generation of advanced nuclear power systems.”

SiGA is a silicon carbide (SiC) composite material that forms the basis for the development of nuclear reactor fuel rods that can survive temperatures far beyond that of current materials. SiGA’s multi-layered SiC composite cladding structure is sealed with a fully-SiC joining process, enabling exceptional stability during operational temperature cycling. This material provides greater stability and safety at temperatures up to 1900° C, well beyond that of metal fuel rod claddings. SiGA cladding would also enable higher powers and longer fuel lifetimes, thereby enhancing overall reactor performance and economics. GA-EMS has been under contract with the Department of Energy (DOE) to support the Accident Tolerant Fuel Program and advance GA-EMS’ silicon carbide fuel cladding technology for future deployment in U.S. nuclear reactors.

“We look forward to continuing our partnership with the DOE and the national labs to accelerate the irradiation testing to demonstrate the performance of fueled SiGA cladded rods. The planned test series progressively builds up performance data to show that SiGA cladding can effectively contain the fuel and any gasses that are produced when subjected to irradiation and high temperature,” said Dr. Christina Back, vice president of GA-EMS Nuclear Technologies and Materials. “In parallel, we are scaling up to full size, 12-foot long SiGA rods and will then be doing the irradiation testing in actual commercial reactors with deployment targeted for the mid-2030 timeframe. We remain committed to bringing SiGA’s unique safety and efficiency benefits to the nation’s nuclear fleet.”  

About General Atomics Electromagnetic Systems
General Atomics Electromagnetic Systems (GA-EMS) develops innovative technologies to create breakthrough solutions supporting operational environments from undersea to space. From electromagnetic, power generation and energy storage systems and space systems and satellites, to hypersonic, missile defense, and laser weapon systems, GA-EMS offers an expanding portfolio of capabilities for defense, government, and national security customers. GA-EMS also provides commercial products and services targeting the hazardous waste remediation, oil and gas, and nuclear energy industries.

For further information, visit Accident Tolerant Fuel | General Atomics
Media Contact:  EMS-MediaRelations@ga.com

Acknowledgement: This press release is based upon work supported by the U.S. Department of Energy (Office of Nuclear Energy); Idaho National Lab; and Oak Ridge National Lab under Award Number DE-NE0009235, “SiC Cladding Development.”  Disclaimer: Neither the U.S. Government, nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information disclosed.