This technical paper proposes the Photonic-Stabilized Micro-Wormhole (PSMW), a conceptual model for high-density energy delivery using a phased-array fiber architecture. The model explores the engineering logic required to stabilize a micro-scale wormhole metric by converging "squeezed" vacuum states (negative energy) through a distributed network of hollow-core photonic crystal fibers. Key Concepts: Energy Delivery: Utilizing Quantum Vacuum Squeezing to generate negative energy density. Containment: Using Hollow-Core Fiber Optics to transport exotic states without decoherence. Scaling: Applying the principle of Coherent Beam Combining, where focal intensity $(I_{focal})$ scales by the square of the number of fibers ($N^2$). Goal: To provide a theoretical roadmap for the infrastructure needed to achieve localized spacetime modulation. Author Note: This work is a conceptual thought experiment authored by a 16-year-old independent researcher. While macro-scale transport remains speculative due to current energy limitations, this paper focuses on the mathematical and engineering feasibility of the delivery architecture itself.