Towards Magnetic Field Quantum Memory: A Theoretical Framework for Frequency-Addressed Data Storage Using Quantum Superposition and P-Wave Magnetis

We propose a theoretical framework for quantum data storage utilizing magnetic fields

as the physical medium, with frequency-based addressing through quantum             

 superposition states. Unlike conventional memory systems that rely on spatial        

 addressing, our approach encodes data addresses in quantum states, making the system

 robust against physical displacement of the magnetic medium.                         

  We demonstrate mathematically that coherent accumulation of N sensors could yield    

  N-squared signal amplification, addressing the weak-signal problem in magnetic field

  detection. Furthermore, we explore how photon-magnon entanglement enables            

  quantum-state addressing.                                                            

  The recent discovery of p-wave magnetism in nickel iodide (NiI2) may provide a       

  potential material platform for future experimental investigation, as the intrinsic 

  spiral spin structures could form natural frequency channels.                        

  Keywords: quantum memory, magnetic storage, frequency addressing, p-wave magnetism, 

  photon-magnon coupling