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1. Introduction

When the plasma density is increased sufficiently, quantum effects become very interesting. This includes degeneracy effects, which becomes important when $T<<T_F$, $T$ is the plasma temperature, $T_F=E_F/k_B$ is the Fermi temperature, defined in Fermi energy as $E_F=\left({\hslash }^2/2m\right){\left(3{\pi }^2{n}_0\right)}^{2/3}$, $k_B$ is Boltzmann’s constant, $\hslash$ is the reduced Planck constant. In this model, particle dispersive effects tend to be important for short scale-lengths (comparable to the characteristic de-Broglie length) when $\hslash {\omega }_p/k_B{T}_F\approx 1$, ${\omega }_p$ is the plasma frequency. In quantum kinetic theory, these effects can be well modeled using the perturbation theory.

In plasmas, in order to further improve these models, the electron spin is taken into account, which introduces a magnetic dipole force, spin precession, and spin magnetization currents into the picture [1–4].

In fact, there has been an increasing interest in plasmas of low-temperature and high densities, where quantum properties tend to be important [5–8]. Promising applications include quantum wells [9], spintronics [10], and plasmonics [11]. Quantum plasma effects can also be of interest in experiments with solid density targets [12]. Important classifications of dense plasmas include whether they are strongly or weakly coupled, and whether they are degenerate or nondegenerate [1]. Several works [5, 13–15] have applied quantum plasma effects, for example, in X-ray Thomson scattering in high energy density plasmas provide experimental techniques for accessing narrow bandwidth spectral lines [2], so as to detect frequency shifts due to quantum effects [13], and the next generation intense laser-solid density plasma interaction experiments [14].

Besides, quantum or degenerate plasmas are of great interest due to their important applications in modern technology and astrophysics. Such plasmas have generated a lot of interest in the last decade owing to their importance in many areas of physics such as semiconductors, metals, microelectronics [16] carbon nanotubes, quantum dots, and quantum wells [17–19]. Degenerate plasmas also play an important role in dense astrophysical objects like plasmas in the interior of stars and neutron stars [20]. The effect of trapping in a degenerate investigated in a plasma comprises degenerate electrons and nondegenerate ions in the presence of a quantizing magnetic field [4].

The usual perturbative treatment of magnetic effects like Zeeman splitting of atomic energy levels in a strong field regime does not apply in such a situation, but instead, the Coulomb forces act as a perturbation to the magnetic forces.

Owing to the extreme confinement of electrons in the transverse direction, the Coulomb force becomes much more effective in binding the electrons along the magnetic field direction [21]. As is well known, electron gas magnetization in a weak magnetic field has two independent parts; (i) paramagnetic, and (ii) the diamagnetic parts. The intrinsic or spin magnetic moment of electrons gives rise to Pauli paramagnetism. The diamagnetic part is due to the fact that the orbital motion of electrons becomes quantized in a magnetic field.

As a fact, the field of quantum plasma physics is becoming of an increasing current interest [22–25], motivated by its potential applications in modern technology (e.g., metallic and semiconductor nanostructures-such as metallic nanoparticles, metal clusters, thin metal films, spintronics, nanotubes, quantum well and quantum dots, nano-plasmonic devices, quantum X-ray free-electron lasers, etc.). In dense quantum plasmas and in the Fermi gas of metals, the number densities of degenerate electrons are extremely high so that their wave functions overlap, and therefore electrons obey the Fermi-Dirac statistics. The Fermi degenerate dense plasma may also arise when a pellet of hydrogen is compressed to many times the solid density in the fast ignition scenario for inertial confinement fusion (ICF) [26, 27].

Our work is of high current interest in experiments and theory-experiment comparisons are becoming possible, e.g., via Thomson scattering using free electron lasers, e.g., [5]. The increasing accuracy of these experiments will be a driving force for theory developments in the near future.

In the present work, we limit ourselves to considering only weakly coupled degenerate plasmas, where effects of ion viscosity are not considered because as ion viscosities can normally be neglected as long as the wave period is much larger than the time scale of the ion correlations and the damping rate due to the viscosities is much smaller than the work frequency of the wave [28].

We investigated the effects of static magnetic field on energy states and degeneracy of electrons in dense plasma. Using perturbation theory, two cases are considered, strongly and weakly magnetized electrons. Perturbed energy eigenvalues $\mathrm{\Delta }E$ are calculated to high accuracy. The energy of spin orbit coupling in plasma, which plays a crucial role in the study of energy states of plasma electrons, is also calculated.

2. Basic Set of Equations

In degenerate plasmas, physical parameters like density, magnetic field, and temperature vary over a wide range of values. For example, the degenerate electron number density may exceed the solid matter density by many orders of magnitude in white dwarfs, neutron stars, and in the next generation of inertially compressed materials in intense laser-solid target interaction experiments.

The theory presented here is of most interest for systems where at least one of the parameters $\hslash {\omega }_p/m{c}^2$ or $\mu B/m{c}^2$ is not too small. Examples include e.g., laser-plasma interactions, solid state plasmas, and strongly magnetized systems.

The following parameters may be used for experimental applications. The number density and the magnetic field have the values of the order of 10²⁶ cm⁻³ and 10¹⁰$G$, respectively [4]. These numbers used to calculate the Fermi energy and the Fermi temperature as $T_F=9.14108\times {10}^8$ K and have taken the electron temperature $T<<T_F$ [29].

We assume electrons in plasmas to be of a quantum medium of many body system. Such an assumption is due to the fact that the solutions obtained have characteristic sizes of atomic order.

Let us assume that we have a magnetic field $\overrightarrow{B}$ applied to unperturbed quantum plasma system with Hamiltonian given by:$$\begin{array}{}\text{(1)}& H\equiv \frac{P^2}{2m}+V\left(r\right)+\aleph \left(r\right)\overrightarrow{L}·\overrightarrow{S},\end{array}$$

where, $\overrightarrow{L}$- the angular momentum vector, $\overrightarrow{S}$- the spin vector of electrons, and $\aleph \left(r\right)$—the energy of spin orbit coupling in plasmas, which has an essential role in the study of energy levels of plasma electrons. $V\left(r\right)$ is a type of potential in the system.

In the presence of a magnetic field, we have to introduce to (1) both (i) $W_{\mu B}$ as the interaction energy between the orbital magnetic moment $\overrightarrow{\mu }$ of the electrons and the magnetic induction,$$\begin{array}{}\text{(2)}& W_{\mu B}=-\overrightarrow{\mu }·\overrightarrow{B},\overrightarrow{\mu }=-\frac{e}{2m}\overrightarrow{L},\end{array}$$

and (ii) $W_{SB}$ as the interaction energy between the spin magnetic moment ${\overrightarrow{\mu }}_S$ and the magnetic induction,$$\begin{array}{}\text{(3)}& W_{SB}=-{\overrightarrow{\mu }}_S·\overrightarrow{B},\overrightarrow{\mu }=-\frac{e}{m}\overrightarrow{S}.\end{array}$$

For simplicity, let us consider a static magnetic field directed to $z$-direction $\left(\overrightarrow{B}={\overrightarrow{e}}_{z}B\right)$.

The total Hamiltonian (1) for spinning electrons reads:$$\begin{array}{}\text{(4)}& H\equiv H_0+W_S+W_B,\end{array}$$

where, $W_S=\aleph \left(r\right)\overrightarrow{L}·\overrightarrow{S}$, $W_B=\left(1/2\right){\overrightarrow{\omega }}_{ce}·\left(\overrightarrow{L}+2\overrightarrow{S}\right)$, ${\omega }_{ce}=\left(eB/m\right)$ is the electron cyclotron frequency, and $H_0=\left(P^2/2m\right)+V\left(r\right)$.

$W_S$ and $W_B$ are now considered as two perturbed terms, and let us now determine the energy levels of the eigenvalue equation for the Hamiltonian (4) using perturbation theory by considering and specify the relative values between $W_S$ and $W_B$.

Two cases will be considered, i.e., (i) strongly magnetized electrons $W_B>>W_S$, and (ii) weakly magnetized electrons $W_B<<W_S$.

3. Strongly Magnetized Plasma

If the magnetic field $\overrightarrow{B}$ is very strong such that $W_B>>W_S$, it is justifiable to consider only $W_S$ as a perturbed quantity, and the unperturbed Hamiltonian reads:$$\begin{array}{}\text{(5)}& H_{01}\equiv H_0+\frac{1}{2}{\omega }_{ce}\left(L_z+2S_z\right).\end{array}$$

It is easy to check that the operators $H_0,L^2,S^2,L_z$, and $S_z$ are all commutes with the unperturbed Hamiltonian (5), and hence the eigenfunction corresponding to (5) may be represented as ${\mathrm{\Psi }}_{n,l,m,m_s}$.

Accordingly, Schrodinger equation may have the form:$$\begin{array}{}\text{(6)}& H_{01}{\mathrm{\Psi }}_{n,l,m,m_s}\equiv E_{nlm{m}_s}^0{\mathrm{\Psi }}_{n,l,m,m_s},\end{array}$$

where,$$\begin{array}{}\text{(7)}& E_{nlm{m}_s}^0=E_{nl}^0+\frac{\hslash }{2}{\omega }_{ce}\left(m+2m_s\right),\end{array}$$

is the eigenvalue of the unperturbed Hamiltonian $H_{01}$.

For values $m_s=-\left(1/2\right)$; $m$ and $m_s=\left(1/2\right)$; $m-2$, then $m+2m_s=m-1$ for both cases and we have degeneracy of order two. For fixed states $n=2$; $l=1$, we have six possible states corresponding to $m=\left(-1,0,1\right)$; $m_s=\left(-\left(1/2\right),\left(1/2\right)\right)$. These six states define six possible different eigenfunctions, two of them are degenerate, and the rest are nondegenerate as indicated in Table 1.

Table 1

Degenerate, and nondegenerate electron states in magnetized plasma.

From (7), it is clear that, using strong magnetic field—to confine the plasma—will not eliminate completely the degeneracy but it functioning to reduce the degeneracy.

Let us consider now the perturbation theory to calculate the electron energy levels in plasmas, it will be very important to know if the state under investigation is degenerate or not. This is because calculation methodology is different for both cases.

The perturbed energy eigenvalues of the four nondegenerate states is given by$$\begin{array}{}\text{(8)}& \mathrm{\Delta }E=⟨{\mathrm{\Psi }}_{n,l,m,m_s}\left|W_s\right|{\mathrm{\Psi }}_{n,l,m,m_s}⟩.\end{array}$$

For degenerate states, let us make use of the above case.

Let $m_1=m$; $m_2=m-2$ and $s_1=-\left(1/2\right)$; $s_2=\left(1/2\right)$

and assume the degenerate states$$\begin{array}{}\text{(9)}& {\mathrm{\Psi }}_1={\mathrm{\Psi }}_{n,l,m_1,m_{s1}};\end{array}$$$$\begin{array}{}\text{(10)}& {\mathrm{\Psi }}_2={\mathrm{\Psi }}_{n,l,m_2,m_{s2}}.\end{array}$$

Besides, we define$$\begin{array}{}\text{(11)}& E_{ij}=⟨{\mathrm{\Psi }}_{n,l,m_i,m_{si}}\left|W_s\right|{\mathrm{\Psi }}_{n,l,m_j,m_{sj}}⟩,i,j=1,2.\end{array}$$

For the degenerate case, the perturbation theory requires the vanishing of the determinant of the unperturbed Hamiltonian $W_s$, which represents a matrix formed of the different eigen functions of the unperturbed terms corresponding to same energy, i.e.,$$\begin{array}{}\text{(12)}& \left[\begin{array}{cc}{E}_{11}-\mathrm{\Delta }E& E_{12}\\ E_{21}& E_{22}-\mathrm{\Delta }E\end{array}\right]=0.\end{array}$$

Relation (11) determines the possible values of $\mathrm{\Delta }E$ for degenerate state. The functions used are eigenfunctions for $J_z$, i.e., $W_s$ has the eigenfunctions$$\begin{array}{}\text{(13)}& {\mathrm{\Psi }}_1\Rightarrow {\mathrm{\Psi }}_{l-\left(1/2\right)},\end{array}$$$$\begin{array}{}\text{(14)}& {\mathrm{\Psi }}_2\Rightarrow {\mathrm{\Psi }}_{l+\left(1/2\right)}.\end{array}$$

Accordingly, the off-diagnoal terms of (11) vanish due to the orthognality of the wave functions, i.e.,$$\begin{array}{}\text{(15)}& {\left(\mathrm{\Delta }E\right)}_1=⟨{\mathrm{\Psi }}_1\left|W_s\right|{\mathrm{\Psi }}_1⟩,\end{array}$$or$$\begin{array}{}\text{(16)}& {\left(\mathrm{\Delta }E\right)}_2=⟨{\mathrm{\Psi }}_2\left|W_s\right|{\mathrm{\Psi }}_2⟩.\end{array}$$

Relation (13) shows that perturbation theory in the presence of strong magnetic field $\left(W_B>>W_s\right)$ has eliminated the plasma electron’s degeneracy. Besides, whenever the perturbed state is degenerate or not; $\mathrm{\Delta }E$ is given by the average value of $W_s=\aleph \left(r\right)\overrightarrow{L}·\overrightarrow{S}$ in the state ${\mathrm{\Psi }}_{n,l,m,m_s}$.

It is clear from above that the perturbation theory, the presence of external magnetic field, has succeeded to eliminate completely the degeneracy, i.e., only one eigenfunction ${\mathrm{\Psi }}_i$ for each eigenvalue ${\left(\mathrm{\Delta }E\right)}_i$. Besides, regardless the perturbed state is degenerate or not, the energy $\mathrm{\Delta }E$ is given by considering the average of $W_s=\aleph \left(r\right)\overrightarrow{L}·\overrightarrow{S}$ with respect to the eigenfunction ${\mathrm{\Psi }}_{n,l,m,m_s}$.

From (13) it is easy to evaluate ${\left(\mathrm{\Delta }E\right)}_{1,2}$ as$$\begin{array}{}\text{(17)}& {\left(\mathrm{\Delta }E\right)}_{1,2}=m_{\left(1,2\right)}{m}_{s\left(1,2\right)}{\hslash }^2{\aleph }_{nl}\left(r\right),\end{array}$$

where,$$\begin{array}{}\text{(18)}& {\aleph }_{nl}\left(r\right)=⟨{\mathrm{\Psi }}_{n,l,m_{\left(1,2\right)},m_{s\left(1,2\right)}}\left|\aleph \left(r\right)\right|{\mathrm{\Psi }}_{n,l,m_{\left(1,2\right)},m_{s\left(1,2\right)}}⟩.\end{array}$$

Now, the perturbed energy of (14) should be added to (7), i.e.,$$\begin{array}{}\text{(19)}& E_{nlm{m}_s}=E_{nl}^0+\frac{\hslash }{2}{\omega }_{ce}\left(m+2m_s\right)+m{m}_s{\hslash }^2{\aleph }_{nl}\left(r\right),\end{array}$$

which shows the complete nondegeneracy of the final state due the third term on right hand side of (16).

4. Weakly Magnetized Plasma

In this case the electron spin orbit coupling $W_s$ is assumed to be much greater than $W_B$, $W_B<<W_s$ and the perturbed Hamiltonian reads:$$\begin{array}{}\text{(20)}& H\equiv \frac{1}{2}{\omega }_{ce}\left(L_z+2S_z\right),\end{array}$$

while the unperturbed Hamiltoninan reads:$$\begin{array}{}\text{(21)}& H\equiv H^0+\aleph \left(r\right)\overrightarrow{L}·\overrightarrow{S}.\end{array}$$

From Pauli’s spin theory, which has the same Hamiltonian (18), the constants of motion are $H,L^2,S^2,J^2,J_z$ and the eigenfunctions and eigenvalues of (18) will have the form:$$\begin{array}{}\text{(22)}& \mathrm{\Psi }={\mathrm{\Psi }}_{nlj{m}_j},\end{array}$$$$\begin{array}{}\text{(23)}& E_{nlj{m}_j}\Rightarrow \begin{array}{c}{E}_{nl}^0+\left(l+1\right){\hslash }^2{\aleph }_{nl}\left(r\right),j=l+\frac{1}{2},\\ E_{nl}^0-\left(l+1\right){\hslash }^2{\aleph }_{nl}\left(r\right),j=l-\frac{1}{2}.\end{array}\end{array}$$

Both eigenvalues in (20) has degeneracy of order $\left(2j+1\right)$, and since the operators $J_z$.

Commutes with the Hamiltonian, therefore, the allowed eigenvalues of $J_z$ in the state function ${\mathrm{\Psi }}_{nlj{m}_j}$ will have the same energy given by (20). Besides, $J_z$ commutes with $H^0,W_B,W_s$ and therefore the perturbation matrix which determines the perturbed energy $\mathrm{\Delta }E$ will be diagonal in this case also. Accordingly, the vanishing its elements yields:$$\begin{array}{}\text{(24)}& \begin{array}{c}\mathrm{\Delta }E=\frac{1}{2}{\omega }_{ce}⟨{\mathrm{\Psi }}_{nlj{m}_j}\left|L_z+2S_z\right|{\mathrm{\Psi }}_{nlj{m}_j}⟩=\frac{1}{2}{\omega }_{ce}⟨{\mathrm{\Psi }}_{nlj{m}_j}\left|J_z+S_z\right|{\mathrm{\Psi }}_{nlj{m}_j}⟩\\ =\frac{1}{2}{\omega }_{ce}\left[\hslash m_j+⟨{\mathrm{\Psi }}_{nlj{m}_j}\left|S_z\right|{\mathrm{\Psi }}_{nlj{m}_j}⟩\right].\\ \end{array}\end{array}$$

It is clear that the appearance of first term on the right hand side of (21), $\left(1/2\right){\omega }_{ce}\hslash m_j$, is due to the external static magnetic field, functioning to remove completely the degeneracy.

To calculate $⟨{\mathrm{\Psi }}_{nlj{m}_j}\left|S_z\right|{\mathrm{\Psi }}_{nlj{m}_j}⟩$, we note that ${\mathrm{\Psi }}_{nlj{m}_j}$ is not an eigenfunction for $S_z$ or$L_z$. Therefore, we can use the following mathematical rule:$$\begin{array}{}\text{(25)}& ⟨\gamma JM\left|\overrightarrow{A}\right|\gamma JM⟩=⟨\gamma JM\left|\overrightarrow{J}\right|\gamma JM⟩·\frac{⟨\gamma JM\left|\overrightarrow{A}·\overrightarrow{J}\right|\gamma JM⟩}{⟨\gamma JM\left|{\overrightarrow{J}}^2\right|\gamma JM⟩},\end{array}$$

where, $\overrightarrow{A}$ is an arbitrary operator, $\gamma$ any additional quantum number, and $\left|\gamma JM\right.⟩$ is an eigenket of the operators that $J^2$ and $J_z$.

Taking the $z$-component of $\overrightarrow{A}$ as $S_z$, then$$\begin{array}{}\text{(26)}& ⟨\gamma JM\left|S_z\right|\gamma JM⟩=⟨\gamma JM\left|J_z\right|\gamma JM⟩·\frac{⟨\gamma JM\left|\overrightarrow{S}·\overrightarrow{J}\right|\gamma JM⟩}{⟨\gamma JM\left|{\overrightarrow{J}}^2\right|\gamma JM⟩}=\frac{m_j}{j\left(j+1\right)\hslash }⟨\gamma JM\left|\overrightarrow{S}·\overrightarrow{J}\right|\gamma JM⟩·\end{array}$$

Set the scatter product $\overrightarrow{S}·\overrightarrow{J}=\left(1/2\right)\left(J^2+S^2-L^2\right)$ into (23), we get$$\begin{array}{}\text{(27)}& ⟨\gamma JM\left|S_z\right|\gamma JM⟩=m_j\hslash \frac{j\left(j+1\right)+s\left(s+1\right)-l\left(l+1\right)}{2j\left(j+1\right)}.\end{array}$$

Set (24) into (21) we obtain $\mathrm{\Delta }E$ the shift in energy levels as:$$\begin{array}{}\text{(28)}& \mathrm{\Delta }E=\frac{\hslash }{2}{\omega }_{ce}{m}_{j}G,\end{array}$$$$\begin{array}{}\text{(29)}& G=1+\frac{j\left(j+1\right)+s\left(s+1\right)-l\left(l+1\right)}{2j\left(j+1\right)},\end{array}$$

where, $G$ is the well known electron Lande’s factor or the spectroscopic factor (lies between 1 and 2), which measures the plasma electrons energy levels. $G$, plays a crucial role in degenerate plasmas when considering fusion burning waves’ ignition and propagation.

However, the outcome of fusion burning waves in nondegenerate plasmas is limited by the strength of ion-electron Coulomb collisions and subsequent energy loss mechanisms as electron heat conduction and radiation emission (Bremsstrahlung).

Relation (26) is in agreement with (37) as per [30].

It is clear that the shift in energy levels $\mathrm{\Delta }E$ depends on the quantum number $m_j$, which removes the degeneracy as mentioned before. $\mathrm{\Delta }E$ Also strongly depend on the Lande’s factor $G$, hence the quantum numbers of the plasma electron states.

For instants, let us consider the following two cases, i.e.,$$\begin{array}{}\text{(30)}& j=\left(l-\frac{1}{2}\right)\Rightarrow G=\frac{2l}{2l+1},j=\left(l+\frac{1}{2}\right)\Rightarrow G=\frac{2\left(l+1\right)}{2l+1}.\end{array}$$

Therefore, in the presence of weak magnetic field $W_B<<W_s$ we have the following energy states:$$\begin{array}{}\text{(31)}& E=E_{nl}^0+\frac{\hslash }{2}{\omega }_{ce}{m}_j\frac{2l}{2l+1}-\hslash \left(l+1\right){\aleph }_{nl}\left(r\right)\text{for}j=\left(l-\frac{1}{2}\right),\end{array}$$$$\begin{array}{}\text{(32)}& E=E_{nl}^0+\frac{\hslash }{2}{\omega }_{ce}{m}_j\frac{2\left(l+1\right)}{2l+1}+\hslash l{\aleph }_{nl}\left(r\right)\text{for}j=\left(l+\frac{1}{2}\right).\end{array}$$

In case of neglecting electron spin, $\left(\stackrel{\rightharpoonup }{S}=0\right)$, the interaction Hamiltonian is reduced to $\approx \left(1/2\right){\overrightarrow{\omega }}_{ce}·\stackrel{\rightharpoonup }{L}$ and finally the plasma electron’s energy $E$ is reduced to,$$\begin{array}{}\text{(33)}& E=E_{nl}^0+\frac{\hslash }{2}{\omega }_{ce}{m}_j.\end{array}$$

5. Results and Conclusions

In this work, we have investigated the effects of static magnetic field on the energy states and degeneracy of electrons in quantized dense plasma. Using perturbation theory, two cases are considered, strongly and weakly magnetized electrons. Perturbed energy eigenvalues $\mathrm{\Delta }E$are calculated analytically to high accuracy in both cases. Let us summarize major results obtained in this work:

5.1. In Strong Magnetic Field

5.2. In Weak Magnetic Field

When the plasma electrons become degenerate, the electron de Broglie wavelength becomes large compared with the mean interparticle spacing and quantum mechanical considerations are of paramount importance.

From (7), it is clear that, using strong magnetic field—to confine the plasma—will not eliminate completely the degeneracy, but it functions to reduce the degeneracy, while from (13), the perturbation theory has eliminated the plasma electron’s degeneracy for eigenfunctions$$\begin{array}{}\text{(34)}& {\mathrm{\Psi }}_1\Rightarrow {\mathrm{\Psi }}_{l-\left(1/2\right)},\end{array}$$$$\begin{array}{}\text{(35)}& {\mathrm{\Psi }}_2\Rightarrow {\mathrm{\Psi }}_{l+\left(1/2\right)}.\end{array}$$

Besides, regardless of whether the perturbed state is degenerate or not, the energy $\mathrm{\Delta }E$ is given by considering the average of $W_S=\aleph \left(r\right)\overrightarrow{L}·\overrightarrow{S}$ with respect to the eigenfunction ${\mathrm{\Psi }}_{n,l,m,m_s}$.

It is clear from above that the perturbation theory, in the presence of external magnetic field, has succeeded to eliminate completely the degeneracy, i.e., only one eigenfunction ${\mathrm{\Psi }}_i$ for each eigenvalue ${\left(\mathrm{\Delta }E\right)}_i$.

For weakly magnetized plasma, the energy correction $\mathrm{\Delta }E$ depends on the quantum number $m_j$, which removes the degeneracy. Besides, $\mathrm{\Delta }E$also strongly depends on the Lande’s factor $G$, hence the quantum numbers of the plasma electron state.

The theory presented here is of most interest for systems where at least one of the parameters $\hslash {\omega }_p/m{c}^2$ or ${\mu }_{s}B/m{c}^2$ is not too small. Examples include e.g., laser-plasma interactions, astrophysical objects, solid state plasmas, and strongly magnetized systems.

As we have seen above, the addition of a magnetic field results in two extra terms in the Hamiltonian. The first arises because the electron is charged. The second term that arises from a magnetic field is the coupling to the spin. Combining the two terms linear in $B$ gives the so-called plasma Zeeman Hamiltonian.

By using the results presented here, a unified treatment of the Zeeman effect becomes possible over the entire range of magnetic fields presently employed in e.g., fusion plasma, where the influence of the Zeeman effect on the plasma temperature measurements has been demonstrated to be significant in many cases.

Authors are very interested to investigate, in due course, the application of their methods to

(i)

A relativistic dense plasma immersed in oscillating inhomogeneous magnetic field.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

This research was funded by the Deanship of Scientific Research at Princess Nourah bint Abdulrahman University through the Fast-track Research Funding Program.