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In [[quantum mechanics]], '''eigenspinors''' are thought of as [[basis vector]]s representing the general spin state of a particle. Strictly speaking, they are not vectors at all, but in fact [[spinors]]. For a single spin 1/2 particle, they can be defined as the [[eigenvectors]] of the [[Pauli matrices]]. | |||
== General eigenspinors == | |||
In quantum mechanics, the [[Spin (physics)|spin]] of a particle or collection of particles is [[quantization (physics)|quantized]]. In particular, all particles have either half integer or integer spin. In the most general case, the eigenspinors for a system can be quite complicated. If you have a collection of [[Avogadro's number]] of particles, each one with two (or more) possible spin states, there would be no hope of writing down a complete set of eigenspinors. However, eigenspinors are very useful when dealing with the spins of a very small number of particles. | |||
== The spin 1/2 particle == | |||
The simplest and most illuminating example of eigenspinors is for a single spin 1/2 particle. A particle's spin has three components, corresponding to the three [[Three-dimensional space|spatial]] dimensions: <math>S_x</math>, <math>S_y</math>, and <math>S_z</math>. For a spin 1/2 particle, there are only two possible [[eigenstates]] of spin: spin up, and spin down. Spin up is denoted as the column matrix: | |||
<math>\chi_+ = \begin{bmatrix} | |||
1\\ | |||
0\\ | |||
\end{bmatrix} | |||
</math> | |||
and spin down is | |||
<math>\chi_- = \begin{bmatrix} | |||
0\\ | |||
1\\ | |||
\end{bmatrix} | |||
</math>. | |||
Each component of the angular momentum thus has two eigenspinors. By convention, the z direction is chosen as having the <math>\chi_+</math> and <math>\chi_-</math> states as its eigenspinors. The eigenspinors for the other two directions follow from this convention: | |||
<math>S_z</math>: | |||
:<math>\chi_+^z = \begin{bmatrix} | |||
1\\ | |||
0\\ | |||
\end{bmatrix} | |||
</math> | |||
:<math>\chi_-^z = \begin{bmatrix} | |||
0\\ | |||
1\\ | |||
\end{bmatrix} | |||
</math> | |||
<math>S_x</math>: | |||
:<math>\chi_+^x = {1 \over \sqrt{2}} \begin{bmatrix} | |||
1\\ | |||
1\\ | |||
\end{bmatrix} | |||
</math> | |||
:<math>\chi_-^x = {1 \over \sqrt{2}} \begin{bmatrix} | |||
1\\ | |||
-1\\ | |||
\end{bmatrix} | |||
</math> | |||
<math>S_y</math>: | |||
:<math>\chi_+^y = {1 \over \sqrt{2}} \begin{bmatrix} | |||
1\\ | |||
i\\ | |||
\end{bmatrix} | |||
</math> | |||
:<math>\chi_-^y = {1 \over \sqrt{2}} \begin{bmatrix} | |||
1\\ | |||
-i\\ | |||
\end{bmatrix} | |||
</math> | |||
==Example usage== | |||
Suppose there is a spin 1/2 particle in a state <math>\chi = {1 \over \sqrt{5}} \begin{bmatrix} | |||
1\\ | |||
2\\ | |||
\end{bmatrix} | |||
</math>. To determine the probability of finding the particle in a spin up state, we simply multiply the state of the particle by the adjoint of the eigenspinor matrix representing spin up, and square the result. Thus, the eigenspinor allows us to sample the part of the particle's state that is in the same direction as the eigenspinor. First we multiply: | |||
<math>c_+ = \begin{bmatrix} | |||
1\ 0\\ | |||
\end{bmatrix} | |||
*\chi = {1 \over \sqrt{5}} | |||
</math>. | |||
Now, we simply square this value to obtain the probability of the particle being found in a spin up state: | |||
<math>P_+ = {1 \over 5}</math> | |||
==Properties== | |||
Each set of eigenspinors forms a [[complete space|complete]], [[orthonormal basis|orthonormal]] basis. This means that any state can be written as a [[linear combination]] of the [[basis (linear algebra)|basis]] spinors. | |||
The eigenspinors are eigenvectors of the Pauli matrices in the case of a single spin 1/2 particle. | |||
==See also== | |||
*[[Spin (physics)|Spin]] | |||
*[[Spinor]] | |||
*[[Eigenvector]] | |||
*[[Pauli matrices]] | |||
==References== | |||
Griffiths, David J. (2005) Introduction to Quantum Mechanics(2nd ed.). Upper Saddle River, NJ: Pearson Prentice Hall. ISBN 0-13-111892-7. | |||
[[Category:Quantum mechanics]] |
Latest revision as of 23:01, 28 September 2013
In quantum mechanics, eigenspinors are thought of as basis vectors representing the general spin state of a particle. Strictly speaking, they are not vectors at all, but in fact spinors. For a single spin 1/2 particle, they can be defined as the eigenvectors of the Pauli matrices.
General eigenspinors
In quantum mechanics, the spin of a particle or collection of particles is quantized. In particular, all particles have either half integer or integer spin. In the most general case, the eigenspinors for a system can be quite complicated. If you have a collection of Avogadro's number of particles, each one with two (or more) possible spin states, there would be no hope of writing down a complete set of eigenspinors. However, eigenspinors are very useful when dealing with the spins of a very small number of particles.
The spin 1/2 particle
The simplest and most illuminating example of eigenspinors is for a single spin 1/2 particle. A particle's spin has three components, corresponding to the three spatial dimensions: , , and . For a spin 1/2 particle, there are only two possible eigenstates of spin: spin up, and spin down. Spin up is denoted as the column matrix: and spin down is .
Each component of the angular momentum thus has two eigenspinors. By convention, the z direction is chosen as having the and states as its eigenspinors. The eigenspinors for the other two directions follow from this convention:
Example usage
Suppose there is a spin 1/2 particle in a state . To determine the probability of finding the particle in a spin up state, we simply multiply the state of the particle by the adjoint of the eigenspinor matrix representing spin up, and square the result. Thus, the eigenspinor allows us to sample the part of the particle's state that is in the same direction as the eigenspinor. First we multiply:
Now, we simply square this value to obtain the probability of the particle being found in a spin up state:
Properties
Each set of eigenspinors forms a complete, orthonormal basis. This means that any state can be written as a linear combination of the basis spinors.
The eigenspinors are eigenvectors of the Pauli matrices in the case of a single spin 1/2 particle.
See also
References
Griffiths, David J. (2005) Introduction to Quantum Mechanics(2nd ed.). Upper Saddle River, NJ: Pearson Prentice Hall. ISBN 0-13-111892-7.