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10: Quantum Physics
https://phys.libretexts.org/Learning_Objects/A_Physics_Formulary/Physics/10%3A_Quantum_Physics
Quantum mechanics, atomic physics, Schrödinger and Dirac equations
13.2: Orbital Magnetic Dipole Moment of the Electron
https://phys.libretexts.org/Courses/Georgia_State_University/GSU-TM-Physics_II_(2212)/13%3A_Atomic_Structure/13.02%3A_Orbital_Magnetic_Dipole_Moment_of_the_Electron
Notice that the direction of the magnetic moment of the electron is antiparallel to the orbital angular momentum, as shown in Figure $\PageIndex{1b}$ . In the Bohr model of the atom, the relations...Notice that the direction of the magnetic moment of the electron is antiparallel to the orbital angular momentum, as shown in Figure $\PageIndex{1b}$ . In the Bohr model of the atom, the relationship between $\vec{\mu}$ and $\vec{L}$ in Equation $\ref{BIG}$ is independent of the radius of the orbit.
1.10: Quantum Physics
https://phys.libretexts.org/Courses/Georgia_State_University/GSU-TM-Introductory_Physics_II_(1112)/zz%3A_Back_Matter/10%3A_13.1%3A_Appendix_J-_Physics_Formulas_(Wevers)/1.10%3A_Quantum_Physics
Quantum mechanics, atomic physics, Schrödinger and Dirac equations
8.3: Orbital Magnetic Dipole Moment of the Electron
https://phys.libretexts.org/Bookshelves/University_Physics/University_Physics_(OpenStax)/University_Physics_III_-_Optics_and_Modern_Physics_(OpenStax)/08%3A_Atomic_Structure/8.03%3A_Orbital_Magnetic_Dipole_Moment_of_the_Electron
A hydrogen atom has magnetic properties because the motion of the electron acts as a current loop. The energy levels of a hydrogen atom associated with orbital angular momentum are split by an externa...A hydrogen atom has magnetic properties because the motion of the electron acts as a current loop. The energy levels of a hydrogen atom associated with orbital angular momentum are split by an external magnetic field because the orbital angular magnetic moment interacts with the field. The potential energy of the hydrogen atom associated with this magnetic interaction is given by $U = -\vec{\mu} \cdot \vec{B}$ .
30.7: Patterns in Spectra Reveal More Quantization
https://phys.libretexts.org/Bookshelves/College_Physics/College_Physics_1e_(OpenStax)/30%3A_Atomic_Physics/30.07%3A_Patterns_in_Spectra_Reveal_More_Quantization
High-resolution measurements of atomic and molecular spectra show that the spectral lines are even more complex than they first appear. In this section, we will see that this complexity has yielded im...High-resolution measurements of atomic and molecular spectra show that the spectral lines are even more complex than they first appear. In this section, we will see that this complexity has yielded important new information about electrons and their orbits in atoms.
6.4: The Zeeman Effect
https://phys.libretexts.org/Bookshelves/Quantum_Mechanics/Essential_Graduate_Physics_-_Quantum_Mechanics_(Likharev)/06%3A_Perturbative_Approaches/6.04%3A_The_Zeeman_Effect
5.7) it has at most two non-vanishing terms, with the Clebsh-Gordan coefficients (5.190): \[\begin{aligned} &\left|j=l \pm 1 / 2, m_{j}\right\rangle \\ &=\pm\left(\frac{l \pm m_{j}+1 / 2}{2 l+1}\right...5.7) it has at most two non-vanishing terms, with the Clebsh-Gordan coefficients (5.190): $\begin{aligned} &\left|j=l \pm 1 / 2, m_{j}\right\rangle \\ &=\pm\left(\frac{l \pm m_{j}+1 / 2}{2 l+1}\right)^{1 / 2}\left|m_{l}=m_{j}-1 / 2, m_{s}=+1 / 2\right\rangle+\left(\frac{l \mp m_{j}+1 / 2}{2 l+1}\right)^{1 / 2}\left|m_{l}=m_{j}+1 / 2, m_{s}=-1 / 2\right\rangle . \end{aligned}$ Taking into account that the operator $\hat{S}_{z}$ gives non-zero brackets only for $m_{s}=m_{s^{\prime}}$ , the \…
7.21: Zeeman effect
https://phys.libretexts.org/Bookshelves/Astronomy__Cosmology/Stellar_Atmospheres_(Tatum)/07%3A_Atomic_Spectroscopy/7.21%3A_Zeeman_effect
When a hot gas which is emitting or absorbing spectrum lines is placed in a magnetic field, the lines become split into several components. This is known as the Zeeman effect, discovered in 1896 by th...When a hot gas which is emitting or absorbing spectrum lines is placed in a magnetic field, the lines become split into several components. This is known as the Zeeman effect, discovered in 1896 by the Dutch spectroscopist P. Zeeman.

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