or to PK03 to help make this particular add-on more useful.
For those who are interested, we'll attempt to give a closer glimpse at wave behavior here and to try to show where the Schr–dinger Equation comes from and what it is.
| Waves and the Wave
equation |
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| Please send questions and/or comments to the
course bboard or to PK03 to help make this particular add-on more useful. |
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For those who are interested, we'll attempt to give a closer glimpse at wave behavior here and to try to show where the Schr–dinger Equation comes from and what it is. |
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| We've already looked at a diagram
representing how the oscillating electric and magnetic
fields of a light wave is pictured (right, top). We can
simplify this by looking at just the electric field, for
example, giving a one-dimensional sine wave for the
variation of the field amplitude with distance along the
x-axis (right, bottom). This equation, represented by the
red curve, is |
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| The maximum amplitude is A
and the wavelength is l. The wave equation for light embodies both wave
behavior and particle behavior. At "short"
wavelengths, geometric shadowing is exlained by this
equation. At "long" wavelengths, interference
and diffraction effects emerge. |
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| At any position along such
a wave pattern (the x-coordinate in one dimension), the
slope can be determined. That is,we see how rapidly the
function (electric field) is changing as we step along
the x-axis. In calculus, this slope is the first
derivative and is represented by |
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| The slopes at various locations are shown here by the solid blue lines. | ||
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| A negative slope is indicated | A negative slope is indicated | A zero slope is indicated |
The curvature of the
function is a measure of how rapidly the function is
curving. (If you think about it, the curvature then is an
indication of how fast the slope is changing at a given
position.) Since a slope in calculus is a rate of change,
the curvature is the rate of change of the first
derivative, which is what's then called the second
derivative and is represented by  . In the illustrations below, the black
lines represent the slope of some function (the function
is not shown but could be the wave functions illustrated
above). The colored curves represent curvature, green
being positive curvature and red being negative
curvature. |
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| Positive slope | Zero slope (as in the rightmost illustration of the wave previously indicated by the blue line) | Negative slope (as in the two leftmost illustrations of the wave) |
If the slope isn't changing, the curvature is zero and the function keeps heading in the direction indicated. If the curvature is positive at a particular point, the slope turns upward. The larger the magnitude of the curvature, the more rapidly the curve breaks. A negative curvature represents the function breaking downward from its current slope. What you see in the sinusoidal behavior of the light wave is that where the amplitude is positive, the curve breaks towards the axis. The amplitude and its second derivative are both positive. When the function crosses the x-axis and thereby becomes negative, the curvature switches to negative as well. Where the amplitude is negative, the curve breaks up towards the axis. The amplitude and its second derivative are both negative. How frequently these switch back and forth is, of course, determined by the wavelength. The overall relationship between the curvature and the amplitude is related to the wavelength in a very simple manner. |
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The above expression is just an alternative way of expressing the wave behavior. For a fixed wavelength, as shown in all the figures above, the ratio of the curvature of the amplitude (numerator on left side of above equation) to the amplitude (denominator on left) is constant (right side of above equation) and generates the sine function shown with whatever wavelength is on the right in the above equation. Now on to a wave equation for matter. |
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| Schr–dinger just takes this equation and uses deBroglie's expression for the wavelength of a particle. |  |
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If we substitute deBroglie's expression into the wave equation, we get an equation (below) in which the relationship between the wave's curvature and its amplitude is determined by the particle's momentum, p. The momentum, p, is in turn related to the kinetic energy. The kinetic energy is the total energy, E, minus the potential energy, which we symbolize by V. The potential energy is related to any forces that might be acting on the particle. What we should recognize here is that the wavelength is no longer constant, but varies throughout space as determined by the manner in which the forces acting on the particle differ from place to place. |
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This is the Schr–dinger Equation (for a one-dimensional system) and is usually algebraically rearranged (for mathematical reasons) and presented as |
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In the case of the hydrogen atom, the above presentation is extended to three dimensions in a straightforward manner giving the three-dimensional Schr–dinger Equation |
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| in which the potential energy is the electrostatic potential of attraction between the electron of charge "e" and the nucleus of general charge "Ze". Obviously, this implies that the wavelength varies in a complicated fashion throughout the three dimensions. |  |
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| Solving the math implies
finding functions, y(x,y,z), that "work". The solution
also gives values of E, the allowed total energy of a
particle/wave being subjected to the forces embodied in
whatever V is relevant. For a nucleus attracting an
electron to it through the Coulomb force, the total
energy solutions are restricted to only certain, discrete
values. They turn out to be identical to the ones given
by Bohr's equation. For each total energy, the results for y(x,y,z) are the various shapes and sizes that we have been displaying. |
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