The program to extend the life of the W80 nuclear warhead recently passed a significant milestone when the National Nuclear Security Administration (NNSA) gave passing grades to the plans to refurbish certain components and the proposed approach to developing component cost estimates.
Passing the milestone confirms that the life extension program (LEP), dubbed the W80-4 LEP, remains on track. The refurbished warhead will be paired with a new cruise missile that is being developed in parallel by the U.S. Air Force, making this the first life extended warhead to be implemented in a new delivery system since the start of the Stockpile Stewardship Program more than 25 years ago.
Lawrence Livermore National Laboratory (LLNL) is the lead nuclear design agency, partnered with Sandia National Laboratories, which is the lead non-nuclear design agency. The work being carried out is driven by military requirements to pair the warhead with the new delivery system and improve weapon safety, security and operational logistics and maintain effectiveness without the need for additional explosive nuclear tests. First production of the W80-4 is planned for 2025.
The W80-4 design concepts have been matured, and the organizations involved are now focused on developing the details involved in producing the W80-4 and certifying that it meets requirements. With the work scope and component cost approach now accepted, the next milestone in this effort will be a detailed weapon development cost report.
“Cost are a pretty big deal for us,” said Alicia Williams, LLNL engineering design lead for the LEP. “We go through these detailed reviews of the costs associated with our scope to help management make informed decisions about whether course correction is needed. The net result with this milestone was confirmation that we’re on the right track.”
How to certify 3D-printed components … without full-scale explosive nuclear testing
LLNL has implemented the project management team needed to meet the scheduling, coordination and integration associated with such a complex project. Significant attention is also being given to assure the design will meet military requirements. The choice of materials to be used in the LEP is just one of the key areas. Some aged materials and components that need replacement cannot be produced exactly as they were originally manufactured. For instance, the main explosive charge needs replacement, but the original high-explosive constituents are not available and therefore must be reconstituted. In addition to refurbishing the warhead itself, considerable attention must be paid to ensuring that it integrates with a brand-new delivery system and can be certified to be safe (won’t go off by accident), secure (can’t be set it off without formal permissions) and effective (will work as designed) without ever conducting a full-scale explosive nuclear test of the system.
In the absence of nuclear testing, researchers use non-nuclear experiments and supercomputers as their virtual test ground. Anyone who has ever made a mistake punching numbers into a calculator knows that the answer is only as good as the numbers that go into the calculation. To verify that the supercomputer simulations reflect reality, and to understand the limitations of these calculations, researchers are validating the computer codes with data from legacy nuclear tests and smaller scale, modern experiments. Together, these experiments and simulations help make sure the judgments made by the W80-4 team are sound.
The next-generation supercomputer, Sierra, with a peak speed of 125-petaFLOPs (floating point operations per second), is now sited at Livermore and will play a central role in certifying the replacement warhead. In addition to the new hardware, code advances have enabled a shift from 2D to 3D modeling, with a special focus on uncertainty quantification. These advances alleviate the need to rely on approximations that were required during the nuclear test era.
Hundreds of tests and experiments are underway at LLNL and Site 300, its experimental test site, to verify that the design options will perform as expected. These experiments helped down-select these design options developed during the earlier “paper study” phase of the LEP (phase 6.1) and will continue to play a role to provide confidence that the final design and associated components and materials will function as required.
“This LEP is driving significant innovation at LLNL,” said Des Pilkington, Weapon Physics and Design program director. “I’m seeing some really creative work in the options, focused on meeting established performance requirements and to minimize costs, always with an eye to what we can ultimately certify will work. That’s where the experimental and code innovations we’ve made under the Stockpile Stewardship Program come into play. They will be critical to the success of our certification plan.”
One area of design innovation is the use of additive manufacturing – commonly referred to as 3D printing – to improve the quality of replacement parts and reduce the cost of production. Researchers are engineering specific material properties into these 3D-printed replacement parts by controlling the microstructure of the printed material. To verify the 3D-printed parts would perform as expected, researchers executed a pair of innovative hydrodynamic (full-scale non-nuclear) experiments in 2016. The data those experiments returned are used to ensure supercomputer simulations accurately represent reality. In addition, extensive material-aging and compatibility experiments are underway to ensure the additively manufactured material will meet performance requirements for the system lifetime.
5 milestones down, 20 more to go
To date, five of the 25 major milestones in the LEP are complete. A mature set of requirements are being refined by the DOD and NNSA, design concepts have been developed, business systems are being put in place to track schedule and budget, and NNSA has made significant investments in the infrastructure at LLNL that will be needed to certify the warhead. LLNL also is leading the effort to reconstitute the capability to manufacture the required insensitive high explosives. Manufacturing of production-scale quantities of the new explosives is underway and on schedule.
The W80-4 program anticipates entering into the development engineering phase (phase 6.3) in 2019, when researchers will test individual components to ensure they will meet military requirements. The next phases in the effort are production engineering (phase 6.4), first production (phase 6.5) and full-scale production (phase 6.6). In order to meet demand for the W80-4 LEP, LLNL has been hiring aggressively over the past couple years. In 2018 alone, more than 100 scientists, engineers and technicians are being brought into the program.
“Even with our Lab hiring at an accelerated rate, and even with the infrastructure improvements NNSA has made here, we could never complete this LEP alone,” said Tom Horrillo, W80-4 life extension program manager. “Our sister lab across the street (Sandia National Laboratories) is playing a central role in this, as are the production plants that are producing components across the country. The Air Force has been a great partner in defining requirements, and NNSA has been indispensable in helping us to roll out the infrastructure and processes we need to get the job done. I’m not overstating things when I say that there would be no LEP without the contributions of everyone on the team.”
The LEP is a collaboration between the DOD and NNSA, with LLNL teaming closely with all of the NNSA laboratories and production sites and the USAF and their missile vendors to deliver a certified warhead into the U.S. stockpile. Key collaborators include Sandia, Kansas City National Security Campus, Y-12 National Security Complex, Pantex Plant, Savannah River Site, Los Alamos National Laboratory, NNSA Livermore Field Office, Albuquerque NNSA W80-4 Program Office, missile program office at Eglin Air Force Base, and Nuclear Weapons Center Kirtland Air Force Base.
“It is so important that we succeed with the W80-4 LEP,” said Williams. “These weapons need to be tremendously safe, secure and effective. We have to meet those expectations just as much as we need to meet the cost and schedule expectations. All told, I can’t help but feel that this is a very exciting time to work at the Lab.”