Phy5645/AngularMomentumProblem: Difference between revisions

Posted by Group 6:

A system is initally in the state:

${\displaystyle \psi (\theta ,\phi )=1/{\sqrt {5}}Y_{1},_{-1}(\theta ,\phi )+{\sqrt {3/5}}Y_{1},_{0}(\theta ,\phi )+1/{\sqrt {5}}Y_{1},_{1}(\theta ,\phi )}$

Let us now find the value of the opperator ${\displaystyle L_{z}}$ acting on the system as well as the probability of finding each value.

We may first rewright the notation for the system as follows;

${\displaystyle |\psi >=1/{\sqrt {5}}|1,-1>+{\sqrt {3/5}}|1,0>+1/{\sqrt {5}}|1,1>}$

${\displaystyle L_{z}}$ acting on the system produces three values for ${\displaystyle l_{z}}$;

${\displaystyle l_{z}=-\hbar ,0,\hbar }$

The probablity for finding the value ${\displaystyle l_{z}=-\hbar }$ is;

${\displaystyle P_{1}=|<1,-1|\psi >|^{2}=|1/{\sqrt {5}}<1,-1|1,-1>+{\sqrt {3/5}}<1-1|1,0>+1/{\sqrt {5}}<1,-1|1,1>|^{2}}$

${\displaystyle =1/5}$

This can easially be verified since;

${\displaystyle <1,-1|1,0>=<1,-1|1,1>=0}$ and ${\displaystyle <1,-1|1,-1>=1}$

The probablites of measuring ${\displaystyle l_{z}=\hbar ,0}$ are give as follows;

${\displaystyle P_{0}=|<1,0|\psi >|^{2}=|{\sqrt {3/5}}<1,0|1,0>|^{2}=3/5}$

${\displaystyle P_{1}=|<1,1|\psi >|^{2}=|{\sqrt {1/5}}<1,1|1,1>|^{2}=1/5}$

Now we will calculate the uncertainties Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle \Delta L_x} and ${\displaystyle \Delta L_{y}}$ and the product ${\displaystyle \Delta L_{x}\Delta L_{y}}$

After measuring ${\displaystyle l_{z}=-\hbar }$ the system will be in the eigenstate ${\displaystyle |lm>=|1,-1>}$, that is ${\displaystyle \psi (\theta ,\phi )=Y_{1},_{-}1(\theta ,|\phi )}$. We will first calculate the expectation values of ${\displaystyle L_{x},L_{y},L_{x}^{2},L_{y}^{2}}$ using ${\displaystyle |1,-1>}$. Symmetry requires ${\displaystyle <1,-1|L_{x}|1,-1>=<1,-1|L_{y}|1,-1>=0}$. Using the relation ${\displaystyle l-1}$ and ${\displaystyle m=-1}$;

${\displaystyle <L_{x}^{2}>=<L_{y}^{2}>=1/2[<L^{2}>-<L_{z}^{2}>]=\hbar ^{2}/2[l(l+1)-m^{2}]=\hbar ^{2}/2}$

${\displaystyle \Delta L_{x}={\sqrt {<L_{x}^{2}>}}=\hbar /{\sqrt {2}}=\Delta L_{y}}$

Therefore;

${\displaystyle \Delta L_{x}\Delta L_{y}={\sqrt {<L_{x}^{2}><L_{y}^{2}>}}=\hbar ^{2}/2}$