22 feb. 2017The Postulates of Quantum Mechanics
http://hyperphysics.phy-astr.gsu.edu/hbase/quantum/qm.html
Varieties of Wave Equations
Early in the 20th century, electrons were shown to have
wave properties, and the
wave-particle duality
became a part of our understanding of nature. The mathematics for
describing the behavior of such electron waves might be expected to be
similar to that for describing classical waves, such as the wave on a
stretched string
or a plane
electromagnetic wave
The
wave equation developed by Erwin Schrodinger in 1926 shows some similarities in its one-dimensional form:
Varieties of Wave Equations
Early
in the 20th century, electrons were shown to have wave properties, and
the wave-particle duality became a part of our understanding of nature.
The mathematics for describing the behavior of such electron waves might
be expected to be similar to that for describing classical waves, such
as the wave on a stretched string
or a plane electromagnetic wave
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The wave equation developed by Erwin Schrodinger in 1926 shows some similarities in its one-dimensional form:
The Postulates of Quantum Mechanics
 | 1. Associated with any particle moving in a conservative field of force
is a wave function which determines everything that can be known about
the system. |
| 2. With every physical observable q there is associated an operator Q,
which when operating upon the wavefunction associated with a definite
value of that observable will yield that value times the wavefunction. |
| 3. Any operator Q associated with a physically measurable property q will be Hermitian. |
| 4. The set of eigenfunctions of operator Q will form a complete set of linearly independent functions. |
| 5. For a system described by a given wavefunction, the expectation
value of any property q can be found by performing the expectation value
integral with respect to that wavefunction. |
| 6. The time evolution of the wavefunction is given by the time dependent Schrodinger equation. |
|
Index
Schrodinger equation concepts |
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The Wavefunction Postulate
It is one of the postulates of quantum mechanics that for a physical system consisting of a particle there is an associated wavefunction.
This wavefunction determines everything that can be known about the
system. The wavefunction is assumed here to be a single-valued function
of position and time, since that is sufficient to guarantee an
unambiguous value of probability of finding the particle at a particular
position and time. The wavefunction may be a complex function, since it
is its product with its complex conjugate which specifies the real
physical probability of finding the particle in a particular state.
|
Index
Schrodinger equation concepts
Postulates of quantum mechanics |
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Constraints on Wavefunction
In order to represent a physically observable system, the wavefunction must satisfy certain constraints:
Further
discussion | 1. Must be a solution of the Schrodinger equation.
2. Must be normalizable. This implies that the wavefunction approaches zero as x approaches infinity.
3. Must be a continuous function of x.
4. The slope of the function in x must be continuous.
| Specifically
|  | must be continuous. |
These constraints are applied to the boundary conditions on the solutions, and in the process help determine the energy eigenvalues. |
|
Index
Schrodinger equation concepts |
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Probability in Quantum Mechanics
The wavefunction
represents the probability amplitude for finding a particle at a given
point in space at a given time. The actual probability of finding the
particle is given by the product of the wavefunction with its complex conjugate (like the square of the amplitude for a complex function).
Since the probability must be = 1 for finding the particle somewhere,
the wavefunction must be normalized. That is, the sum of the
probabilities for all of space must be equal to one. This is expressed
by the integral
Part of a working solution to the Schrodinger equation is the
normalization of the solution to obtain the physically applicable
probability amplitudes.
|
Index
Schrodinger equation concepts |
|
Go Back |
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