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Quantum platforms; Core Technology  Precision-engineered spherical, ridged, wrinkled, or hybrid domes  Controlled local curvature (µm–mm scale) to induce deterministic strain fields  Direct tuning of: o Fermi velocity o Dirac point position o Quantum capacitance o Pseudo-magnetic fields (in engineered geometries)  Fully compatible with Raman-verified strain mapping and DoS modeling Product 1: QP-DOME-SURFACE™ A curvature-engineered dome substrate where the 2D material is conformally transferred onto the surface, experiencing controlled bending and strain dictated by dome geometry. Key Features  Direct exposure of 2D layer for: o Optical probing o Electrical contacting o Surface functionalization  Supports: o Smooth spherical caps o 2D micro-ridges o Micro-tips / toroidal features o Engineered wrinkle fields Parameter Typical Range Dome diameter 50 µm – 10 mm Local curvature radius 5 µm – 5 mm Dome height 0.5 µm – 500 µm 2D flake size 5 µm – 1 mm Substrate Epoxy / PDMS / hybrid polymers Advantages  Maximum DoS tunability per unit curvature  Ideal for quantum capacitance sensors, Raman-DoS correlation, transport studies  Easy integration with electrodes and gates.

Product 2: QP-DOME-EMBED™ Description A mechanically protected architecture where the 2D material is embedded inside an epoxy dome, experiencing curvature-induced strain while being isolated from environmental damage. Key Features  Encapsulated 2D layer for: o Long-term stability o Mechanical robustness o Environmental isolation  Strain locked during curing or tunable via dome deformation  Compatible with optical, capacitive, and acoustic readout Parameter Typical Range Dome diameter 100 µm – 20 mm Embed depth 10 nm – 10 µm Local curvature radius 10 µm – 10 mm Epoxy modulus (tunable) 10 kPa – 5 GPa Thermal stability −40 °C to +120 °C Advantages  Ultra-stable DoS modulation  Reduced defect generation  Ideal for field-deployable sensors, embedded quantum elements, hybrid acoustic– quantum devices Applications  Quantum capacitance sensors  Ultra-low-light & single-photon detectors  Strain-programmable optoelectronics  Pseudo-magnetic-field-based quantum devices  Bio-inspired sensing (olfaction, acoustic–quantum coupling)  Research platforms for curved-space Dirac physics.

Many quantum experiments depend on flat, fragile substrates or cryogenic systems that cannot easily accommodate spatially varying strain, curvature, or multi-material heterogeneity parameters that are increasingly recognized as critical in modulating quantum behavior in 2D and low- dimensional systems. The absence of compact, integrated, and stable solid- state testbeds has become a bottleneck for progress in both fundamental and applied quantum materials science. Therefore, there is a pressing need for a readily available, mechanically robust, and chemically inert platform that can host and probe diverse 2D materials without the need for complex wet chemistry or high-vacuum synthesis. Such a platform should enable rapid experimentation, modular integration of multiple quantum domains, and operability under ambient conditions, thereby accelerating discovery and validation cycles across quantum optics, sensing, and nanoelectronics. The proposed 2D Material Quantum Platform built on a sub-millimeter silicone epoxy dome with distributed 2D layers of varying thickness addresses this challenge by providing a dry, curvature-enhanced, solid-state environment for exploring quantum phenomena without the burden of chemical synthesis or liquid processing. These platforms give the unique advantage to deploy in 2d material based research in different fields..