Difference between revisions of "Atomic Units"

Latest revision as of 00:12, 20 February 2024

Atomic Units

The natural units for describing atomic systems are obtained by setting to unity the three fundamental constants that appear in the hydrogen Hamiltonian, $\hbar =m=e=1$ . One thus arrives at atomic units, such as

length: Bohr radius = $a_{0}={\frac {\hbar ^{2}}{me^{2}}}={\frac {1}{\alpha }}{\frac {\hbar }{mc}}=0.53A$
energy: 1 hartree = ${\frac {e^{4}m}{\hbar ^{2}}}=({\frac {e^{2}}{c\hbar }})^{2}mc^{2}=\alpha ^{2}mc^{2}=27.2\ {\textrm {eV}}$
velocity: $mv^{2}={\frac {e^{4}m}{\hbar ^{2}}}\Rightarrow v={\frac {e^{2}}{\hbar }}=\alpha \cdot c=2.2\times 10^{8}\ {\textrm {cm/s}}$
electric field: ${\frac {e}{a_{0}^{2}}}=5.142\times 10^{9}~{\rm {V/cm}}$

Note: This is the characteristic value for the

n=1

orbit of hydrogen.

As we see above, we can express atomic units in terms of $c$ instead of $e$ by introducing a single dimensionless constant

\alpha ={\frac {e^{2}}{\hbar c}}\approx {\frac {1}{137}}.

The fine structure constant $\alpha$ obtained its name from the appearance of $\alpha ^{2}$ in the ratio of fine structure splitting to the Rydberg; it is the only fundamental constant in atomic physics. As such, it should ultimately be predicted by a complete theory of physics. Whereas precision measurements of other constants are made in atomic physics for purely metrological purposes , $\alpha$ , as a dimensionless constant, is not defined by metrology. Rather, $\alpha$ characterizes the strength of the electromagnetic interaction, as the following example will illustrate. If energy uncertainties become become as large as $\Delta E=mc^{2}$ , the concept of a particle breaks down. This upper bound on the energy uncertainty gives us, via the Heisenberg Uncertainty Principle, a lower bound on the length scale within which an electron can be localized (before e.g. spontaneous pair production may occur) $\Delta \simeq mc^{2}\Rightarrow \Delta p=mc$ , so (uncertainty principle $\Rightarrow$ ) $\Delta x={\frac {\hbar }{mc}}=\lambda _{c}$ Even at this short distance of $\lambda _{c}$ , the Coulumb interaction---while stronger than that in hydrogen at distance $a_{0}$ --- is only:

E_{c}={\frac {e^{2}}{\lambda _{c}}}={\frac {e^{2}mc}{\hbar }}={\frac {e^{2}}{\hbar c}}mc^{2}=\alpha mc^{2}\,,

i.e. in relativistic units the strength of this "stronger" Coulomb interaction is $\alpha$ . The fact that $\alpha ={\frac {1}{137}}$ implies that the Coulomb interaction is weak.

@@ Line 3: / Line 3: @@
 the three fundamental constants that appear in the hydrogen Hamiltonian, <math>\hbar=m=e=1</math>.  One thus arrives at atomic units, such as
-* length: Bohr radius = <math>a_0=\frac{\hbar^2}{me^2}=\frac{1}{\alpha}\frac{\hbar}{mc}=0.53 {\rm \AA}</math>
+<!--<math>\def\AA\unicode{x212B}</math>-->
+* length: Bohr radius = <math>a_0=\frac{\hbar^2}{me^2}=\frac{1}{\alpha}\frac{\hbar}{mc}=0.53 A </math>
 * energy: 1 hartree = <math>\frac{e^4 m}{\hbar^2}=(\frac{e^2}{c\hbar})^2mc^2=\alpha^2 mc^2=27.2\ \textrm{eV}</math>
 * velocity: <math>m v^2=\frac{e^{4}m}{\hbar^2}\Rightarrow v=\frac{e^2}{\hbar}=\alpha\cdot
@@ Line 14: / Line 16: @@
 \alpha=\frac{e^2}{\hbar c}\approx\frac{1}{137}.
 </math>
-The ''fine structure constant''  <math>\alpha</math> obtained its name from the appearance of <math>\alpha^2</math> in the ratio of fine structure splitting to the Rydberg;  it is the only fundamental constant in atomic physics.  As such, it should ultimately be predicted by a complete theory of physics.  Whereas precision measurements of other constants are made in atomic physics for purely metrological purposes (see Appendix \ref{app:metrology) ), <math>\alpha</math>, as a dimensionless constant, is not defined by metrology.  Rather, <math>\alpha</math> characterizes the strength of the electromagnetic interaction, as the following example will illustrate.
+The ''fine structure constant''  <math>\alpha</math> obtained its name from the appearance of <math>\alpha^2</math> in the ratio of fine structure splitting to the Rydberg;  it is the only fundamental constant in atomic physics.  As such, it should ultimately be predicted by a complete theory of physics.  Whereas precision measurements of other constants are made in atomic physics for purely metrological purposes <!-- (see Appendix \ref{app:metrology) ) -->, <math>\alpha</math>, as a dimensionless constant, is not defined by metrology.  Rather, <math>\alpha</math> characterizes the strength of the electromagnetic interaction, as the following example will illustrate.
 If energy uncertainties become become as large as <math>\Delta E=mc^2</math>, the concept of a particle breaks down.  This upper bound on the energy uncertainty gives us, via the Heisenberg Uncertainty Principle, a lower bound on the length scale within which an electron can be localized (before e.g. spontaneous pair production may occur)
-<math>\Delta\simeq mc^2\Rightarrow \Delta p=mc</math>
+<math>\Delta\simeq mc^2\Rightarrow \Delta p=mc</math>, so (uncertainty principle <math>\Rightarrow </math>)
 <math>\Delta x=\frac{\hbar}{mc}=\lambda_c</math>
 Even at this short distance of <math>\lambda_c</math>, the Coulumb
@@ Line 28: / Line 30: @@
 </math>
 i.e. in relativistic units the strength of this "stronger" Coulomb
-interaction is <math>\alpha</math>.  That <math>\alpha=\frac{1}{137}</math> says that the
+interaction is <math>\alpha</math>.  The fact that <math>\alpha=\frac{1}{137}</math> implies that the
 Coulomb interaction is weak.
-<references/>

Difference between revisions of "Atomic Units"

Latest revision as of 00:12, 20 February 2024

Atomic Units

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