Consider the double-slit patterns obtained for electrons and photons in Figure 29.25. Let us explore what happens if we try to follow a particle. It is somewhat disquieting to think that you cannot predict exactly where an individual particle will go, or even follow it to its destination. Those who developed quantum mechanics devised equations that predicted the probability distribution in various circumstances. There is a certain probability of finding the particle at a given location, and the overall pattern is called a probability distribution. After compiling enough data, you get a distribution related to the particle’s wavelength and diffraction pattern. However, each particle goes to a definite place (as illustrated in Figure 29.24). The idea quickly emerged that, because of its wave character, a particle’s trajectory and destination cannot be precisely predicted for each particle individually. Both patterns are probability distributions in the sense that they are built up by individual particles traversing the apparatus, the paths of which are not individually predictable.Īfter de Broglie proposed the wave nature of matter, many physicists, including Schrödinger and Heisenberg, explored the consequences. Then from the uncertainty principle we know that p /2x p / 2 x and p2 p2 p 2 p 2 ( p 0 p 0 and x x 0 in a minimum energy state) Plugging this back into the energy equation gives. (See Figure 29.24.)įigure 29.25 Double-slit interference for electrons (a) and photons (b) is identical for equal wavelengths and equal slit separations. Repeated measurements will display a statistical distribution of locations that appears wavelike. But if you set up exactly the same situation and measure it again, you will find the electron in a different location, often far outside any experimental uncertainty in your measurement. Experiments show that you will find the electron at some definite location, unlike a wave. What is the position of a particle, such as an electron? Is it at the center of the wave? The answer lies in how you measure the position of an electron. Matter and photons are waves, implying they are spread out over some distance.
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