Phy5645/Uncertainty Relations Problem 2: Difference between revisions

Latest revision as of 13:23, 18 January 2014

According to the Heisenberg Uncertanity Principle, $\Delta x\,\Delta p\cong \hbar$ and so $\Delta p\cong {\frac {\hbar }{\Delta x}}$ . On the other hand, as we know that $E={\frac {p^{2}}{2m}}.$ Therefore, $\Delta E={\frac {(\Delta p)^{2}}{2m}}.$

If we plug $\Delta p$ into the energy equation, we obtain $\Delta E\cong {\frac {\hbar ^{2}}{2m(\Delta x)^{2}}}$

Let the length of a side of the box $l=\Delta x\rightarrow 0$

Knowing that the size of a nucleon is about $10^{-12}\,{\text{cm}},$ that their mass $mc^{2}\cong 938\,{\text{MeV}}$ , and that $\hbar c\cong 197\times 10^{-13}\,{\text{MeV}}\cdot {\text{cm}}$ , we can calculate kinetic energy.

$\Delta E\cong {\frac {\hbar ^{2}}{2m(\Delta x)^{2}}}={\frac {\hbar ^{2}c^{2}}{2mc^{2}(\Delta x)^{2}}}={\frac {(197\times 10^{-13}\,{\text{MeV}}\cdot {\text{cm}})^{2}}{(2)(938\,{\text{MeV}})(10^{-12}\,{\text{cm}})^{2}}}\approx 0.2\,{\text{MeV}}$

Back to Heisenberg Uncertainty Principle

@@ Line 1: / Line 1: @@
-This is a problem from the book of W.Greiner named Quantum Mechanics.
-'''Consider a box with a particle (a nucleon) in it. The width of the box is <math>l</math>.  Determine the magnitude of kinetic energy of the particle.'''
-[[Image:Untitled.gif|thumb|425px|a picture of the box taken from the same book]]
 According to the Heisenberg Uncertanity Principle, <math>\Delta x\,\Delta p \cong \hbar</math> and so <math> \Delta p\cong \frac{\hbar}{\Delta x}</math>. On the other hand, as we know that <math>E=\frac{p^2}{2m}.</math>  Therefore,<math>\Delta E= \frac{(\Delta p)^2}{2m}.</math>
@@ Line 13: / Line 6: @@
 Let the length of a side of the box <math>l= \Delta x \rightarrow 0 </math>
-Knowing that the size of a nucleon is about <math>10^{12}\,\text{cm},</math> that their mass <math> mc^2 \cong 938\,\text{MeV}</math>, and that <math>\hbar c\cong 197 \times 10 ^{-13}\,\text{MeV}\cdot\text{cm}</math>, we can calculate kinetic energy.
+Knowing that the size of a nucleon is about <math>10^{-12}\,\text{cm},</math> that their mass <math> mc^2 \cong 938\,\text{MeV}</math>, and that <math>\hbar c\cong 197 \times 10 ^{-13}\,\text{MeV}\cdot\text{cm}</math>, we can calculate kinetic energy.
+<math> \Delta E\cong \frac{\hbar ^2}{2m(\Delta x) ^2}= \frac{\hbar ^2 c ^2}{2mc ^2(\Delta x) ^2 }=  \frac{(197 \times 10 ^{-13}\,\text{MeV}\cdot\text{cm}) ^2} {(2) (938\,\text{MeV}) (10 ^{-12}\,\text{cm})^2}  \approx 0.2\,\text{MeV}</math>
-<math> \Delta E\cong \frac{\hbar ^2}{2m(\Delta x) ^2}= \frac{\hbar ^2 c ^2}{2mc ^2(\Delta x) ^2 }=  \frac{(197 \times 10 ^{-13}\,\text{MeV}\cdot\text{cm}) ^2} {(2) (938\,\text{MeV}) (10 ^{-12}) ^2}  \approx 0.2\,\text{MeV}</math>
+Back to [[Heisenberg Uncertainty Principle#Problems|Heisenberg Uncertainty Principle]]

Phy5645/Uncertainty Relations Problem 2: Difference between revisions

Latest revision as of 13:23, 18 January 2014

Navigation menu

Search