Difference between revisions of "Quantum Mechanics"

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(Expectation value)
(Schrödinger Equation)
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==Schrödinger Equation==
 
==Schrödinger Equation==
TBD
+
===Time-independent equation===
 +
This simplified version of the Schrödinger equation can be used to solve for allowed stationary states. The general form is akin to the eigenvalue problems noted above: the energy operator (<math>\hat{H}</math>) acts on the system state (<math>\Psi</math>) to yield an energy eigenvalue (<math>E</math>):
 +
:<math>E\Psi=\hat H \Psi</math>
 +
For a single non-relativistic particle, the Hamiltonian is known and the Schrödinger equation takes the form:
 +
:<math>E \Psi(\mathbf{r}) = \left[ \frac{-\hbar^2}{2m}\nabla^2 + V(\mathbf{r}) \right] \Psi(\mathbf{r})</math>
 +
 
 +
===Time-dependent equation===
 +
More generally, the time-evolution of the wavefunction should be considered. The full version of the Schrödinger equation thus includes time dependence:
 +
:<math>i \hbar \frac{\partial}{\partial t}\Psi = \hat H \Psi</math>
 +
Again for a single non-relativistic particle, we can write more specifically that:
 +
:<math>i\hbar\frac{\partial}{\partial t} \Psi(\mathbf{r},t) = \left [ \frac{-\hbar^2}{2\mu}\nabla^2 + V(\mathbf{r},t)\right ] \Psi(\mathbf{r},t)</math>
  
 
==Entanglement==
 
==Entanglement==

Revision as of 08:16, 13 October 2014

Quantum mechanics is a theory that describes the interactions of all particles and systems. It underlies all physical phenomena, including scattering.


Wavefunction

A quantum system is completely specified by its Wave Function:

Integral Notation Dirac Notation
     

The wavefunction is typically normalized:

Integral Notation Dirac Notation
     

The distribution of the particle described by is given by:

Integral Notation Dirac Notation
     

In the Copenhagen Interpretation, is the probability of finding the particle at location . In Universal Wave Function interpretations (e.g. MWI), can be thought of as the spatial distribution of the particle. The wavefunction contains all the information one can know about a system. It can thus be thought of as 'being' the particle/system in question. However, the wavefunction can be described in an infinite number of different ways. That is, there is not a unique basis for describing the wavefunction. So, for instance, one can describe the wavefunction using position-space or momentum-space:

These representations can be inter-related (c.f. Fourier transform):

State

Note that the wavefunction describes the state of the system; there are various choices of basis one can use as an expansion.

A basis should be orthonormal:

Integral Notation Dirac Notation
      normalized
      orthogonal

An operator defines a particular convenient basis: one can always expand using the basis defined by an operator, in which case the above are the eigenvectors (or eigenstates) of that basis. This can also be viewed as a vector in the Hilbert space. The Dirac notation (bra-ket notation) is useful in this regard. A particular state is a (column) vector:

Which is a 'ket'. We define a 'bra' (the 'final state') as a (row) vector:

And note that the 'bra' is the conjuagte transpose of the 'ket':

Wave packet

TBD

Heisenberg Indeterminacy Relations

(Also known as Heisenberg Uncertainty Principle.)

Superposition

If and are both allowed states for a given system, then the following state is also allowed:

This leads to a notable consequence:

Notice that the final terms represent 'interference' between the two constituent states. This interference has no classical analogue; it is a quantum effect. Thus a superposition is not merely a 'joining' of the two states (e.g. "the particle can be in state 1 or state 2"), but a truly coherent interference between the two states. The superposition may be more generally written as:

Integral Notation Dirac Notation
     

The distribution of the particle described by is given by:

Integral Notation Dirac Notation
     

Operators

Observables in QM appears as operators ().

Examples: TBD.

Measurement

The transition of the wavefunction into state can be thought of as:

     

When acting on a wavefunction with operator the probability that the wavefunction ends up in state is given by:

     

The solutions take the form of an eigenvalue problem:

The allowed solutions of the equation, for operator , involve an eigenstate with associated eigenvalue . A measurement on a quantum system can be thought of as driving the wavefunction into an eigenstate defined by the operator; the value of the associated observable is then fixed to be the corresponding eigenvalue. (As noted above, the probability of ending up in a particular eigenstate is regulated by the coefficient of that eigenstate in the original wavefunction decomposition.)

Expectation value

A given operator, e.g. , implies an expectation value (for state ) of:

     

If the system is in an eigenstate of the operator:

We know that:

And so:

In other words, the expectation value of an eigenstate is simply the eigenvalue.

Schrödinger Equation

Time-independent equation

This simplified version of the Schrödinger equation can be used to solve for allowed stationary states. The general form is akin to the eigenvalue problems noted above: the energy operator () acts on the system state () to yield an energy eigenvalue ():

For a single non-relativistic particle, the Hamiltonian is known and the Schrödinger equation takes the form:

Time-dependent equation

More generally, the time-evolution of the wavefunction should be considered. The full version of the Schrödinger equation thus includes time dependence:

Again for a single non-relativistic particle, we can write more specifically that:

Entanglement

TBD

Decoherence

TBD

See Also