Dirac quantization: Difference between revisions

Latest revision as of 15:56, 1 July 2018

For a Hamiltonian system without constraints, Dirac quantization can be imposed through the following condition between Poisson brackets and quantum brackets

$\{f_{1},f_{2}\}\rightarrow -{\frac {i}{\hbar }}[{\hat {f}}_{1},{\hat {f}}_{2}]$

being $f_{1}$ and $f_{2}$ functions of the canonical variables and the hat is there to remember that, in the quantum case, one has operators acting on a Hilbert space. The definition of these functions for operators incurs into an ordering problem.

So, for a mechanical system with Hamiltonian $H$ having the following set of canonical equations describing the dynamics

$\{q_{i},p_{k}\}=\delta _{ik},\ \{q_{i},q_{k}\}=0,\ \{p_{i},p_{k}\}=0$

$\partial _{t}p_{i}=\{p_{i},H\},\ \partial _{t}q_{i}=\{q_{i},H\},$

one can postulate a corresponding quantum system with dynamical equations

$[{\hat {q}}_{i},{\hat {p}}_{k}]=i\hbar \delta _{ik},\ [{\hat {q}}_{i},{\hat {q}}_{k}]=0,\ [{\hat {p}}_{i},{\hat {p}}_{k}]=0$

$\partial _{t}{\hat {p}}_{i}=-{\frac {i}{\hbar }}[{\hat {p}}_{i},{\hat {H}}],\ \partial _{t}{\hat {q}}_{i}=-{\frac {i}{\hbar }}[{\hat {q}}_{i},{\hat {H}}].$

The operatorial equations describing time evolution of the operators are now termed Heisenberg equations. In its more general form, Heisenberg equation for an operator $A$ is written, again using Dirac quantization on Poisson brackets, as

$d_{t}{\hat {A}}=\partial _{t}{\hat {A}}-{\frac {i}{\hbar }}[{\hat {A}},{\hat {H}}].$

@@ Line 1: / Line 1: @@
-{{stub}}
 For a Hamiltonian system without constraints, Dirac quantization can be imposed through the following condition between Poisson brackets and quantum brackets
-$$\{f_1,f_2\}\rightarrow -\frac{i}{\hbar}[\hat f_1,\hat f_2]$$
+<math>\{f_1,f_2\}\rightarrow -\frac{i}{\hbar}[\hat f_1,\hat f_2]</math>
-being $f_1$ and $f_2$ functions of the canonical variables and the hat is there to remember that, in the quantum case, one has operators acting on a Hilbert space. The definition of these functions for operators incur into an ordering problem.
+being <math>f_1</math> and <math>f_2</math> functions of the canonical variables and the hat is there to remember that, in the quantum case, one has operators acting on a Hilbert space. The definition of these functions for operators incurs into an ordering problem.
-So, for a mechanical system with Hamiltonian $H$ having the following set of canonical equations describing the dynamics
+So, for a mechanical system with Hamiltonian <math>H</math> having the following set of canonical equations describing the dynamics
-$$\{q_i,p_k\}=\delta_{ik},\ \{q_i,q_k\}=0,\ \{p_i,p_k\}=0$$
+<math>\{q_i,p_k\}=\delta_{ik},\ \{q_i,q_k\}=0,\ \{p_i,p_k\}=0</math>
-$$\partial_t p_i=\{p_i,H\}, \partial_t q_i=\{q_i,H\},$$
+<math>\partial_t p_i=\{p_i,H\},\ \partial_t q_i=\{q_i,H\},</math>
 one can postulate a corresponding quantum system with dynamical equations
-$$[\hat q_i,\hat p_k]=i\hbar\delta_{ik},\ [\hat q_i,\hat q_k]=0,\ [\hat p_i,\hat p_k]=0$$
+<math>[\hat q_i,\hat p_k]=i\hbar\delta_{ik},\ [\hat q_i,\hat q_k]=0,\ [\hat p_i,\hat p_k]=0</math>
+<math>\partial_t \hat p_i=-\frac{i}{\hbar}[\hat p_i,\hat H],\ \partial_t \hat q_i=-\frac{i}{\hbar}[\hat q_i,\hat H].</math>
-$$\partial_t \hat p_i=-\frac{i}{\hbar}[\hat p_i,\hat H], \partial_t \hat q_i=-\frac{i}{\hbar}[\hat q_i,\hat H].$$
+The operatorial equations describing time evolution of the operators are now termed '''Heisenberg equations'''. In its more general form, Heisenberg equation for an operator <math>A</math> is written, again using Dirac quantization on Poisson brackets, as
-The operatorial equations describing time evolution of the operators are now termed '''Heisenberg equations'''.
+<math> d_t\hat A=\partial_t\hat A-\frac{i}{\hbar}[\hat A,\hat H].</math>
 [[Category:methods]]

Dirac quantization: Difference between revisions

Latest revision as of 15:56, 1 July 2018

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