According to our current understanding in quantum mechanics, particles and waves are intrinsically interconnected, and the concept of pure waves or pure particles with no wave properties does not align with this framework. The behavior of particles is described by wave functions, and these wave functions exhibit wave-like properties such as interference and diffraction.
In quantum mechanics, particles are described by wave functions that evolve over time according to Schrödinger's equation. The wave function represents the probability distribution of finding a particle in a particular state or location. This wave function can exhibit wave-like characteristics, such as superposition and interference, which are fundamental aspects of quantum mechanics.
On the other hand, it is important to note that particles also exhibit particle-like behavior in certain circumstances. When measured or observed, particles manifest as localized entities with definite properties, such as position or momentum. This is known as wave function collapse, where the wave function "collapses" to a specific state or measurement outcome.
In summary, the behavior of particles in quantum mechanics is described by wave functions, which inherently have wave-like properties. While particles can exhibit both wave-like and particle-like behavior, the idea of pure waves with no particle properties or pure particles with no wave properties does not align with our current understanding of the quantum nature of the universe.