In quantum physics, particles can exhibit both wave-like and particle-like properties, which is known as wave-particle duality. However, it is important to note that not all matter is purely described as waves. Matter is composed of various fundamental particles, such as electrons, protons, and neutrons, which have both wave-like and particle-like characteristics.
Regarding your question, changing the frequency or amplitude of a wave associated with a particle does not directly result in transforming that particle into a different object or material. The properties and behavior of particles are determined by a combination of factors, including their intrinsic properties (such as mass and charge) and the interactions they have with other particles and fields.
Changing the properties of a particle, such as its energy or momentum, can have different effects depending on the specific situation. For example, altering the energy of an electron can cause it to transition to a different quantum state within an atom, which may have different properties. However, this does not change the fundamental nature of the particle itself or convert it into a different material.
Transformation of one material into another typically involves complex processes such as chemical reactions or nuclear reactions, which go beyond simply manipulating the wave properties of individual particles. These processes often involve rearranging or reconfiguring the atomic or molecular structure of the material.
While quantum physics provides a foundational understanding of matter and its behavior, practical applications and transformations of materials usually require additional considerations beyond wave properties. Fields such as chemistry, materials science, and engineering provide more comprehensive frameworks for understanding and manipulating matter at the macroscopic level.