According to quantum physics, particles can exhibit wave-like behavior, but it's important to note that changing the frequency or amplitude of a wave associated with a particular particle does not directly result in the transformation of one object into another object or material.
The wave-particle duality implies that particles have both wave-like and particle-like characteristics. The wave nature of a particle is described by its wavefunction, which determines the probability distribution of finding the particle at different locations. The frequency and amplitude of the wavefunction are related to the energy and probability amplitudes associated with the particle.
However, transforming one object into another involves more than just changing the wave characteristics. It typically requires complex processes, such as chemical reactions or nuclear reactions, which involve the rearrangement of atoms, the breaking or formation of bonds, or changes in the nucleus of the atoms.
In these processes, the interaction and rearrangement of particles, including electrons and atomic nuclei, are involved. The properties and behavior of these particles are governed by fundamental physical laws, such as the laws of quantum mechanics and the conservation of energy and momentum.
While it is true that changing the energy or momentum of a particle can have effects on its behavior and interactions, simply manipulating the frequency or amplitude of a wave associated with a particle is not sufficient to change one object into another in a meaningful sense. The transformation of objects or materials involves more complex physical processes beyond the characteristics of waves associated with individual particles.