Abstract:
This manuscript presents the engineering specification for the OMEGA-7, a compact steady-state Tokamak designed for the High-Lundquist (S > 10^8) regime.
The design addresses two critical failure modes in commercial fusion:
1. MHD Disruptions: Mitigated via a "Negative-Latency" (<20µs) Torsion Control Network (TCN) running on FPGA, replacing standard reactive PID loops.
2. Neutron Degradation: Mitigated via Cyanate Ester/Polyimide insulation (tested to 10^22 n/cm^2) and an In-Situ Pulse Annealing protocol.
Key Specs:
- Field: 12 Tesla (REBCO HTS)
- Blanket: Liquid FLiBe with Active Beryllium Redox Control
- Control Logic: Inverse Magnetic Curvature Stabilization
We argue that at commercial scales, plasma stability becomes a topological information problem, not just a fluid dynamics problem.
I am looking for rigorous feedback on:
- The FPGA inference latency budget (Section 4.1).
- The thermodynamic stability of the Be-FLiBe redox couple at >550°C.
MohskiBroskiAI•1d ago
The design addresses two critical failure modes in commercial fusion: 1. MHD Disruptions: Mitigated via a "Negative-Latency" (<20µs) Torsion Control Network (TCN) running on FPGA, replacing standard reactive PID loops. 2. Neutron Degradation: Mitigated via Cyanate Ester/Polyimide insulation (tested to 10^22 n/cm^2) and an In-Situ Pulse Annealing protocol.
Key Specs: - Field: 12 Tesla (REBCO HTS) - Blanket: Liquid FLiBe with Active Beryllium Redox Control - Control Logic: Inverse Magnetic Curvature Stabilization
We argue that at commercial scales, plasma stability becomes a topological information problem, not just a fluid dynamics problem.
I am looking for rigorous feedback on: - The FPGA inference latency budget (Section 4.1). - The thermodynamic stability of the Be-FLiBe redox couple at >550°C.