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Certainly! Heisenberg's uncertainty principle states that it is impossible to simultaneously know the exact position and momentum of a subatomic particle with arbitrary precision. This principle arises due to the wave-particle duality inherent in quantum mechanics.

Let's consider the example of an electron. Imagine you want to precisely determine its position. To do so, you would need to shine light or some other form of radiation on the electron and observe the light that scatters off it. However, this interaction affects the electron's momentum. According to the uncertainty principle, the more precisely you try to measure the position of the electron, the more uncertain its momentum becomes.

Conversely, if you want to measure the momentum of the electron accurately, you would need to use a technique like particle scattering or analyzing its wavelength. But in the process of measuring its momentum, you introduce uncertainty in its position. The more precisely you try to determine the momentum, the less precisely you can know the electron's position.

This uncertainty is not due to technological limitations but is an inherent property of the quantum world. It means that there are fundamental limits to our ability to simultaneously know both the position and momentum of a particle.

To summarize, Heisenberg's uncertainty principle manifests in situations where attempts to measure the position and momentum of a particle become entangled. The more precisely we try to measure one of these properties, the less precise our knowledge becomes about the other, ultimately leading to uncertainty in both.

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