What are the recommended anti-matter containment features for the table?

When handling antimatter in a research setting, the design of the containment table is paramount for safety and stability. The primary recommended feature is a robust magnetic confinement system. This utilizes precisely calibrated magnetic fields to levitate and isolate antimatter particles, preventing contact with ordinary matter. The table must integrate an ultra-high vacuum chamber, reducing particle density to minimize annihilation events. Multi-layer radiation shielding, often combining lead, polyethylene, and boronated materials, is essential to absorb secondary particles and gamma rays produced during potential minor breaches. The structure itself requires non-magnetic, high-strength materials like certain aluminum alloys or composites to avoid field interference. Integrated, redundant monitoring sensors for temperature, pressure, and radiation must feed into a dedicated failsafe system capable of initiating emergency protocols. Furthermore, the table design should incorporate passive safety elements such as secondary electrostatic traps and a geometrically secure configuration that directs any energy release away from operators. These integrated features transform a standard table into a critical platform for secure antimatter experimentation, where engineering for failure is the core principle of operational success.