Atomic spectral line
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In physics, atomic spectral lines are formed when an electron makes a transition from a particular energy level of an atom, to a lower energy state. The two states are states in which the electron is bound to the atom, so the transition is sometimes referred to as a "bound–bound" transition, as opposed to a transition in which the electron is ejected out of the atom completely ("bound–free" transition) into a continuum state, leaving an ionized atom. A photon with an energy equal to the energy difference between the levels is released in the process, which forms the spectral line. The frequency [\nu] at which the spectral line occurs is related to the energy [E] by Planck's law [E=h\nu] where [h] is Planck's constant. The atomic radiation produced is characterized by an emission coefficient and an absorption coefficient. Knowing these two coefficients will allow the calculation of the intensity of radiation from an emitting region by use of the equation of radiative transfer
Emission and absorption coefficients
The emission of atomic line radiation may be described by an emission coefficient [\epsilon] with units of energy/time/volume/solid angle. ε dt dV dΩ is then the energy emitted by a volume element [dV] in time [dt] into solid angle [d\Omega]. For atomic line radiation:
- [\epsilon = \fracn_2 A_\,]
- [\kappa' = \frac~(n_1 B_-n_2 B_) \,]
In the case of local thermodynamic equilibrium, the densities of the atoms, both excited and unexcited, may be calculated from the Maxwell-Boltzmann distribution, but for other cases, (e.g. lasers) the calculation is more complicated.
The above equations have ignored the influence of the spectral line shape. To be accurate, the above equations need to be multiplied by the (normalized) spectral line shape, in which case the units will change to include a 1/Hz term.
The Einstein coefficients
In 1916, Albert Einstein proposed that there are essentially three processes occurring in the formation of an atomic spectral line. The three processes are referred to as spontaneous emission, induced emission and absorption and with each is associated an Einstein coefficient which is a measure of the probability of that particular process occurring.
Spontaneous emission
Spontaneous emission is the process by which an electron "spontaneously" (i.e without any outside influence) decays from a higher energy level to a lower one. The process is described by the Einstein coefficient [A_] which gives the probability per unit time that an electron in state 2 with energy [E_2] will decay spontaneously to state 1 with energy [E_1], emitting a photon with an energy [E_2-E_1=h\nu]. If [n_i] is the number density of atoms in state i then the change in the number density of atoms in state 1 per unit time due to spontaneous emission will be:
- [\left(\frac\right)_}=A_n_2]
Stimulated emission
Stimulated emission (also known as induced emission) is the process by which an electron is induced to jump from a higher energy level to a lower one by the presence of electromagnetic radiation at (or near) the frequency of the transition. The process is described by the Einstein coefficient [B_] which gives the probability per unit time per unit energy density of the radiation field, that an electron in state 2 with energy [E_2] will decay to state 1 with energy [E_1], emitting a photon with an energy [E_2-E_1=h\nu]. The change in the number density of atoms in state 1 per unit time due to induced emission will be:
- [\left(\frac\right)_}=B_n_2 I(\nu)]
Stimulated emission is one of the fundamental processes that led to the development of the laser.
Photoabsorption
Absorption is the process by which a photon is absorbed by the atom, causing an electron to jump from a lower energy level to a higher one. The process is described by the Einstein coefficient [B_] which gives the probability per unit time per unit energy density of the radiation field, that an electron in state 1 with energy [E_1] will absorb a photon with an energy [E_2-E_1=h\nu] and jump to state 2 with energy [E_2]. The change in the number density of atoms in state 1 per unit time due to absorption will be:
- [\left(\frac\right)_}=-B_n_1 I(\nu)]
Detailed balancing
The Einstein coefficients are fixed probabilities associated with each atom, and do not depend on the state of the gas of which the atoms are a part. Therefore, any relationship that we can derive between the coefficients at, say, thermal equilibrium will be valid universally. At equilibrium, we will have a simple balancing, in which the net change in the number of any excited atoms is zero, being balanced by loss and gain due to all processes. With respect to bound-bound transitions, we will have detailed balancing as well, which states that the net exchange between any two levels will be balanced. This is because the probabilities of transition cannot be affected by the presence or absence of other excited atoms. Detailed balance requires that the change in time of the number of atoms in level 1 due to the above three processes be zero:
- [0=A_n_2+B_n_2I(\nu)-B_n_1 I(\nu)\,]
From the Maxwell-Boltzmann distribution we have for the number of excited atomic specie i:
- [\frac= \frac}]
- [I(\nu)=\frac-1}]
- [F(\nu)=\frac]
- [F(\nu)=\frac]
- [A_g_2e^+B_g_2e^\frac-1}=B_g_1\frac-1}]
- [\frac}}=\frac~F(\nu)]
- [\frac}}=\frac]
Oscillator strengths
Oscillator strength [f_] is defined by:
- [a_=\frac\,f_]
- [A_=\frac~\frac~f_]
- [B_=\frac\,f_]
- [B_=\frac~\frac~f_]
See also
References
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