This work introduces seven fundamentally new classes of laser devices enabled by graphene and the Ψ-field, as established in the Quarkbase Cosmology framework. Unlike conventional semiconductor lasers—dependent on bandgaps, population inversion, or electron–hole recombination—these Ψ-driven architectures rely entirely on pressure-field dynamics within a frictionless etheric plasma. Each laser class is derived from experimentally testable predictions and theoretical results previously published in the Quarkbase literature, including curvature-dependent absorbance, longitudinal-mode coherence, superconductivity without Cooper pairs, plasmo-Ψ coupling, and pressure-driven anisotropy. The seven architectures include: Ψ-Longitudinal Laser Curvature-Tunable κ-Laser Ψ-Phase Laser Hyperconductive Thermal Ψ-Laser Plasmo-Ψ Hybrid Laser Gap-Free Graphene Ψ-Laser Anisotropic Pressure-Driven Ψ-Laser Collectively, they outline a complete taxonomy of coherent emitters that do not require electronic band physics at all. This work establishes graphene as the first material capable of supporting fully Ψ-based photonic devices and defines a new technological domain in light generation based on etheric pressure dynamics.