\section{Broader Impacts} \textbf{Heilmeier Questions: Who cares? Why now? What difference will it make?} Sections 2 through 5 established the complete technical research plan. They addressed what has been done, what is new and why it will succeed, how to measure success, and what could prevent success. This section addresses the remaining Heilmeier questions. It connects technical methodology to economic and societal impact. \textbf{Who cares?} Three stakeholder groups face the same economic constraint: high operating costs driven by staffing requirements. The nuclear industry faces uncompetitive per-megawatt costs for small modular reactors. Datacenter operators need hundreds of megawatts of continuous clean power for AI infrastructure. Clean energy advocates need nuclear power to compete economically with fossil alternatives. All three require autonomous control with safety guarantees. \textbf{What difference will it make?} This research addresses a \$21--28 billion annual cost barrier. It enables economically viable small modular reactors for datacenter power. It establishes a generalizable framework for safety-critical autonomous systems across critical infrastructure. \textbf{Why now?} Exponentially growing AI infrastructure demands have transformed this longstanding challenge into an immediate crisis. A market now demands solutions that did not exist before. Nuclear power presents both a compelling application domain and an urgent economic challenge. Recent interest in powering artificial intelligence infrastructure has renewed focus on small modular reactors (SMRs) for hyperscale datacenters requiring hundreds of megawatts of continuous power. SMRs deployed at datacenter sites minimize transmission losses and eliminate emissions, but at this scale, nuclear power economics demand careful attention to operating costs. The U.S. Energy Information Administration's Annual Energy Outlook 2022 projects advanced nuclear power entering service in 2027 will cost \$88.24 per megawatt-hour~\cite{eia_lcoe_2022}. Datacenter electricity demand is projected to reach 1,050 terawatt-hours annually by 2030~\cite{eesi_datacenter_2024}. Nuclear power supplying this demand would generate total annual costs exceeding \$92 billion. Operations and maintenance represents a substantial component. The EIA estimates fixed O\&M costs alone account for \$16.15 per megawatt-hour. Variable O\&M costs are embedded in fuel and operating expenses~\cite{eia_lcoe_2022}. Combined, O\&M-related costs represent approximately 23--30\% of total levelized cost. For projected datacenter demand, this translates to \$21--28 billion annually. \textbf{What difference will it make?} This research directly addresses the \$21--28 billion annual O\&M cost barrier. High-assurance autonomous control makes small modular reactors economically viable for datacenter power while maintaining nuclear safety standards. Beyond immediate economic impact, the methodology establishes a generalizable framework for safety-critical autonomous systems across critical infrastructure. Current nuclear operations require full control room staffing for each reactor—whether large conventional units or small modular designs. For large reactors producing 1,000+ MW, staffing costs spread across substantial output. Small modular reactors producing 50-300 MW face the same staffing requirements with far lower output. This makes per-megawatt costs prohibitive. These staffing requirements drive the economic challenge threatening SMR deployment for datacenter applications. Synthesizing provably correct hybrid controllers from formal specifications automates routine operational sequences currently requiring constant human oversight. This enables a fundamental shift from direct operator control to supervisory monitoring, where operators oversee multiple autonomous reactors rather than manually controlling individual units. The correct-by-construction methodology proves critical for this transition. Traditional automation approaches cannot provide sufficient safety guarantees for nuclear applications. Regulatory requirements and public safety concerns demand the highest levels of assurance. This research formally verifies both the discrete mode-switching logic and the continuous control behavior. It produces controllers with mathematical proofs of correctness. These guarantees enable automation to safely handle routine operations: startup sequences, power level changes, and normal operational transitions. These operations currently require human operators to follow written procedures. Operators will remain in supervisory roles to handle off-normal conditions and provide authorization for major operational changes. The routine cognitive burden of procedure execution shifts to provably correct automated systems that cost far less to operate. SMRs represent an ideal deployment target for this technology. Nuclear Regulatory Commission certification requires extensive documentation of control procedures, operational requirements, and safety analyses written in structured natural language. As described in our approach, these regulatory documents can be translated into temporal logic specifications using tools like FRET, then synthesized into discrete switching logic using reactive synthesis tools, and finally verified using reachability analysis and barrier certificates for the continuous control modes. The infrastructure of requirements and specifications already exists as part of the licensing process, creating a direct pathway from existing regulatory documentation to formally verified autonomous controllers. Beyond reducing operating costs for new reactors, this research establishes a generalizable framework for autonomous control of safety-critical systems. The methodology translates operational procedures into formal specifications. It synthesizes discrete switching logic. It verifies continuous mode behavior. This methodology applies to any hybrid system with documented operational requirements. Potential applications include chemical process control, aerospace systems, and autonomous transportation. Similar economic and safety considerations favor increased autonomy with provable correctness guarantees in these domains. Demonstrating this approach in nuclear power—one of the most regulated and safety-critical domains—will establish both the technical feasibility and regulatory pathway for broader adoption across critical infrastructure. This section answered three critical Heilmeier questions: \textbf{Who cares?} Three stakeholder groups face the same constraint. The nuclear industry faces an economic crisis for small modular reactors due to per-megawatt staffing costs. Datacenter operators need hundreds of megawatts of continuous clean power for AI infrastructure. Clean energy advocates need nuclear power to be economically competitive. All three require autonomous control with safety guarantees. \textbf{Why now?} Two forces converge to create urgency. \textit{First: exponentially growing demand.} AI infrastructure creates immediate need for economical nuclear power at datacenter scale. Projections show datacenter electricity demand reaching 1,050 terawatt-hours annually by 2030. \textit{Second: technical maturity.} Formal methods tools have matured sufficiently to make compositional hybrid verification computationally achievable. What was theoretically possible but practically intractable a decade ago is now feasible. The problem is urgent. The tools exist. \textbf{What difference will it make?} This research addresses a \$21--28 billion annual cost barrier. It enables autonomous control with mathematical safety guarantees. Beyond immediate economic impact, the methodology establishes a generalizable framework for safety-critical autonomous systems across critical infrastructure. It extends beyond nuclear power to any safety-critical system requiring provable correctness. Sections 2 through 6 addressed all but one of the Heilmeier questions. Section 2 established what has been done and what limits current practice. It identified the verification gap. Section 3 explained what is new and why it will succeed. It presented three innovations enabling compositional verification. Section 4 defined how to measure success through TRL advancement from 3 to 5. Section 5 identified what could prevent success and provided contingencies. This section connected technical methodology to economic and societal impact. One final Heilmeier question remains: How long will it take? Section 8 provides the answer. It presents a detailed schedule with milestones and deliverables.