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The distinction between waves and particles arises from the historical development of our understanding of nature and the behavior of matter and energy. Traditionally, waves are associated with phenomena characterized by the propagation of oscillations or disturbances through a medium, while particles are considered as discrete, localized entities with distinct positions and trajectories.

However, in the early 20th century, experimental observations and theoretical developments in the field of quantum mechanics challenged this classical view. Scientists discovered that the behavior of matter and energy at the microscopic level, such as electrons and photons (particles of light), cannot be fully described solely in terms of classical particles or classical waves. This realization gave rise to the concept of wave-particle duality.

Wave-particle duality suggests that entities like electrons and photons exhibit properties of both particles and waves, depending on how they are observed or measured. This duality means that these entities can behave as particles, with discrete positions and trajectories, and also exhibit wave-like properties, such as interference and diffraction.

For example, in the famous double-slit experiment, when individual particles, such as electrons or photons, are sent through a barrier with two slits, they create an interference pattern on the screen behind the barrier, as if they had behaved like waves. This interference pattern arises due to the constructive and destructive interference of the wave-like probabilities associated with the particles' positions.

On the other hand, in other experiments where the particle's position is precisely measured, its behavior resembles that of a classical particle, showing a definite position but with uncertain momentum.

Wave-particle duality suggests that at the quantum level, particles are described by wave functions, which mathematically represent the probability distribution of finding a particle at a given location. The wave function evolves according to a wave-like equation (such as the Schrödinger equation), and its square magnitude provides the probability of finding the particle at different positions.

In summary, the distinction between waves and particles blurs at the quantum level due to wave-particle duality. Particles can exhibit wave-like properties, and waves can exhibit particle-like properties, depending on the experimental setup and the measurement being performed. The wave-particle duality is a fundamental concept of quantum mechanics and has profound implications for our understanding of the nature of matter and energy.

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