Term symbol
In quantum mechanics, the term symbol is an abbreviated description of the (total) angular momentum quantum numbers in a multielectron atom (however, even a single electron can be described by a term symbol). Each energy level of an atom with a given electron configuration is described by not only the electron configuration but also its own term symbol, as the energy level also depends on the total angular momentum including spin. The usual atomic term symbols assume LS coupling (also known as Russell–Saunders coupling or spin–orbit coupling). The ground state term symbol is predicted by Hund's rules.
The use of the word term for an energy level is based on the Rydberg–Ritz combination principle, an empirical observation that the wavenumbers of spectral lines can be expressed as the difference of two terms. This was later summarized by the Bohr model, which identified the terms (multiplied by hc, where h is the Planck constant and c the speed of light) with quantized energy levels and the spectral wavenumbers (again multiplied by hc) with photon energies.
Tables of atomic energy levels identified by their term symbols have been compiled by the National Institute of Standards and Technology. In this database, neutral atoms are identified as I, singly ionized atoms as II, etc.[1] Neutral atoms of the chemical elements have the same term symbol for each column in the sblock and pblock elements, but may differ in dblock and fblock elements, if the ground state electron configuration changes within a column. Ground state term symbols for chemical elements are given below.
LS coupling and symbol
For light atoms, the spin–orbit interaction (or coupling) is small so that the total orbital angular momentum L and total spin S are good quantum numbers. The interaction between L and S is known as LS coupling, Russell–Saunders coupling (named after Henry Norris Russell and Frederick Albert Saunders, who described this in 1925.[2]) or spin–orbit coupling. Atomic states are then well described by term symbols of the form
where
 S is the total spin quantum number. 2S + 1 is the spin multiplicity, which represents the number of possible states of J for a given L and S, provided that L ≥ S. (If L < S, the maximum number of possible J is 2L + 1).[3] This is easily proven by using J_{max} = L + S and J_{min} = L − S, so that the number of possible J with given L and S is simply J_{max} − J_{min} + 1 as J varies in unit steps.
 J is the total angular momentum quantum number.
 L is the total orbital quantum number in spectroscopic notation. The first 17 symbols of L are:
L = 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 ... S P D F G H I K L M N O Q R T U V (continued alphabetically)[note 1]
The nomenclature (S, P, D, F) is derived from the characteristics of the spectroscopic lines corresponding to (s, p, d, f) orbitals: sharp, principal, diffuse, and fundamental; the rest being named in alphabetical order from G onwards, except that J is omitted. When used to describe electron states in an atom, the term symbol usually follows the electron configuration. For example, one lowlying energy level of the carbon atom state is written as 1s^{2}2s^{2}2p^{2 3}P_{2}. The superscript 3 indicates that the spin state is a triplet, and therefore S = 1 (2S + 1 = 3), the P is spectroscopic notation for L = 1, and the subscript 2 is the value of J. Using the same notation, the ground state of carbon is 1s^{2}2s^{2}2p^{2 3}P_{0}.[1]
Small letters refer to individual orbitals or oneelectron quantum numbers, whereas capital letters refer to manyelectron states or to their quantum numbers.
Terms, levels, and states
The term symbol is also used to describe compound systems such as mesons or atomic nuclei, or molecules (see molecular term symbol). For molecules, Greek letters are used to designate the component of orbital angular momenta along the molecular axis.
For a given electron configuration
 The combination of an S value and an L value is called a term, and has a statistical weight (i.e., number of possible microstates) equal to (2S+1)(2L+1);
 A combination of S, L and J is called a level. A given level has a statistical weight of (2J+1), which is the number of possible microstates associated with this level in the corresponding term;
 A combination of S, L, J and M_{J} determines a single state.
The product as a number of possible microstates with given S and L is also a number of basis states in the uncoupled representation, where S, m_{S}, L, m_{L} (m_{S} and m_{L} are zaxis components of total spin and total orbital angular momentum respectively) are good quantum numbers whose corresponding operators mutually commute. With given S and L, the eigenstates in this representation span function space of dimension , as and . In the coupled representation where total angular momentum (spin + orbital) is treated, the associated microstates (or eigenstates) are and these states span the function space with dimension of
as . Obviously the dimension of function space in both representation must be the same.
As an example, for , there are (2×1+1)(2×2+1) = 15 different microstates (= eigenstates in the uncoupled representation) corresponding to the ^{3}D term, of which (2×3+1) = 7 belong to the ^{3}D_{3} (J = 3) level. The sum of for all levels in the same term equals (2S+1)(2L+1) as the dimensions of both representations must be equal as described above. In this case, J can be 1, 2, or 3, so 3 + 5 + 7 = 15.
Term symbol parity
The parity of a term symbol is calculated as
where is the orbital quantum number for each electron. means even parity while is for odd parity. In fact, only electrons in odd orbitals (with odd) contribute to the total parity: an odd number of electrons in odd orbitals (those with an odd such as in p, f,...) correspond to an odd term symbol, while an even number of electrons in odd orbitals correspond to an even term symbol. The number of electrons in even orbitals is irrelevant as any sum of even numbers is even. For any closed subshell, the number of electrons is which is even, so the summation of in closed subshells is always an even number. The summation of quantum numbers over open (unfilled) subshells of odd orbitals ( odd) determines the parity of the term symbol. If the number of electrons in this reduced summation is odd (even) then the parity is also odd (even).
When it is odd, the parity of the term symbol is indicated by a superscript letter "o", otherwise it is omitted:
 ^{2}P^{o}
_{½} has odd parity, but ^{3}P_{0} has even parity.
Alternatively, parity may be indicated with a subscript letter "g" or "u", standing for gerade (German for "even") or ungerade ("odd"):
 ^{2}P_{½,u} for odd parity, and ^{3}P_{0,g} for even.
Ground state term symbol
It is relatively easy to calculate the term symbol for the ground state of an atom using Hund's rules. It corresponds with a state with maximum S and L.
 Start with the most stable electron configuration. Full shells and subshells do not contribute to the overall angular momentum, so they are discarded.
 If all shells and subshells are full then the term symbol is ^{1}S_{0}.
 Distribute the electrons in the available orbitals, following the Pauli exclusion principle. First, fill the orbitals with highest value with one electron each, and assign a maximal m_{s} to them (i.e. +½). Once all orbitals in a subshell have one electron, add a second one (following the same order), assigning m_{s} = −½ to them.
 The overall S is calculated by adding the m_{s} values for each electron. According to Hund's first rule, the ground state has all unpaired electron spins parallel with the same value of m_{s}, conventionally chosen as +½. The overall S is then ½ times the number of unpaired electrons. The overall L is calculated by adding the values for each electron (so if there are two electrons in the same orbital, add twice that orbital's ).
 Calculate J as
 if less than half of the subshell is occupied, take the minimum value J = L − S;
 if more than halffilled, take the maximum value J = L + S;
 if the subshell is halffilled, then L will be 0, so J = S.
As an example, in the case of fluorine, the electronic configuration is 1s^{2}2s^{2}2p^{5}.
 Discard the full subshells and keep the 2p^{5} part. So there are five electrons to place in subshell p ().
 There are three orbitals () that can hold up to electrons. The first three electrons can take m_{s} = ½ (↑) but the Pauli exclusion principle forces the next two to have m_{s} = −½ (↓) because they go to already occupied orbitals.
+1 0 −1 ↑↓ ↑↓ ↑  S = ½ + ½ + ½ − ½ − ½ = ½; and L = 1 + 0 − 1 + 1 + 0 = 1, which is "P" in spectroscopic notation.
 As fluorine 2p subshell is more than half filled, J = L + S = ^{3}⁄_{2}. Its ground state term symbol is then ^{2S+1}L_{J} = ^{2}P_{3⁄2}.
Atomic term symbols of the chemical elements
In the periodic table, because atoms of elements in a column usually have the same outer electron structure, and always have the same electron structure in the "sblock" and "pblock" elements (see block (periodic table)), all elements may share the same ground state term symbol for the column. Thus, hydrogen and the alkali metals are all ^{2}S_{1⁄2}, the alkali earth metals are ^{1}S_{0}, the boron column elements are ^{2}P_{1⁄2}, the carbon column elements are ^{3}P_{0}, the pnictogens are ^{4}S_{3⁄2}, the chalcogens are ^{3}P_{2}, the halogens are ^{2}P_{3⁄2}, and the inert gases are ^{1}S_{0}, per the rule for full shells and subshells stated above.
Term symbols for the ground states of most chemical elements[4] are given in the collapsed table below (with citations for the heaviest elements here). In the dblock and fblock, the term symbols are not always the same for elements in the same column of the periodic table, because open shells of several d or f electrons have several closely spaced terms whose energy ordering is often perturbed by addition of an extra complete shell to form the next element in the column.
For example, the table shows that the first pair of vertically adjacent atoms with different groundstate term symbols are V and Nb. The ^{6}D_{1/2} ground state of Nb corresponds to an excited state of V 2112 cm^{−1} above the ^{4}F_{3/2} ground state of V, which in turn corresponds to an excited state of Nb 1143 cm^{−1} above the Nb ground state.[1] These energy differences are small compared to the 15158 cm^{−1} difference between the ground and first excited state of Ca,[1] which is the last element before V with no d electrons.
Term symbol of the chemical elements  

Group →  1  2  3  4  5  6  7  8  9  10  11  12  13  14  15  16  17  18  
↓ Period  
1  H ^{2}S_{1⁄2} 
He ^{1}S_{0}  
2  Li ^{2}S_{1⁄2} 
Be ^{1}S_{0} 
B ^{2}P_{1⁄2} 
C ^{3}P_{0} 
N ^{4}S_{3⁄2} 
O ^{3}P_{2} 
F ^{2}P_{3⁄2} 
Ne ^{1}S_{0}  
3  Na ^{2}S_{1⁄2} 
Mg ^{1}S_{0} 
Al ^{2}P_{1⁄2} 
Si ^{3}P_{0} 
P ^{4}S_{3⁄2} 
S ^{3}P_{2} 
Cl ^{2}P_{3⁄2} 
Ar ^{1}S_{0}  
4  K ^{2}S_{1⁄2} 
Ca ^{1}S_{0} 
Sc ^{2}D_{3/2} 
Ti ^{3}F_{2} 
V ^{4}F_{3/2} 
Cr ^{7}S_{3} 
Mn ^{6}S_{5/2} 
Fe ^{5}D_{4} 
Co ^{4}F_{9/2} 
Ni ^{3}F_{4} 
Cu ^{2}S_{1⁄2} 
Zn ^{1}S_{0} 
Ga ^{2}P_{1⁄2} 
Ge ^{3}P_{0} 
As ^{4}S_{3⁄2} 
Se ^{3}P_{2} 
Br ^{2}P_{3⁄2} 
Kr ^{1}S_{0}  
5  Rb ^{2}S_{1⁄2} 
Sr ^{1}S_{0} 
Y ^{2}D_{3/2} 
Zr ^{3}F_{2} 
Nb ^{6}D_{1/2} 
Mo ^{7}S_{3} 
Tc ^{6}S_{5/2} 
Ru ^{5}F_{5} 
Rh ^{4}F_{9/2} 
Pd ^{1}S_{0} 
Ag ^{2}S_{1⁄2} 
Cd ^{1}S_{0} 
In ^{2}P_{1⁄2} 
Sn ^{3}P_{0} 
Sb ^{4}S_{3⁄2} 
Te ^{3}P_{2} 
I ^{2}P_{3⁄2} 
Xe ^{1}S_{0}  
6  Cs ^{2}S_{1⁄2} 
Ba ^{1}S_{0} 
La ^{2}D_{3/2} 
Hf ^{3}F_{2} 
Ta ^{4}F_{3/2} 
W ^{5}D_{0} 
Re ^{6}S_{5/2} 
Os ^{5}D_{4} 
Ir ^{4}F_{9/2} 
Pt ^{3}D_{3} 
Au ^{2}S_{1⁄2} 
Hg ^{1}S_{0} 
Tl ^{2}P_{1⁄2} 
Pb ^{3}P_{0} 
Bi ^{4}S_{3⁄2} 
Po ^{3}P_{2} 
At ^{2}P_{3⁄2} 
Rn ^{1}S_{0}  
7  Fr ^{2}S_{1⁄2} 
Ra ^{1}S_{0} 
Ac ^{2}D_{3/2} 
Rf ^{3}F_{2} 
Db ^{4}F_{3/2}? 
Sg ^{5}D_{0}? 
Bh ^{6}S_{5/2}? 
Hs 
Mt 
Ds 
Rg 
Cn 
Nh 
Fl 
Mc 
Lv 
Ts 
Og  
Ce ^{1}G_{4} 
Pr ^{4}I_{9/2} 
Nd ^{5}I_{4} 
Pm ^{6}H_{5/2} 
Sm ^{7}F_{0} 
Eu ^{8}S_{7/2} 
Gd ^{9}D_{2} 
Tb ^{6}H_{15/2} 
Dy ^{5}I_{8} 
Ho ^{4}I_{15/2} 
Er ^{3}H_{6} 
Tm ^{2}F_{7/2} 
Yb ^{1}S_{0} 
Lu ^{2}D_{3/2}  
Th ^{3}F_{2} 
Pa ^{4}K_{11/2} 
U ^{5}L_{6} 
Np ^{6}L_{11/2} 
Pu ^{7}F_{0} 
Am ^{8}S_{7/2} 
Cm ^{9}D_{2} 
Bk ^{6}H_{15/2} 
Cf ^{5}I_{8} 
Es ^{4}I_{15/2} 
Fm ^{3}H_{6} 
Md ^{2}F_{7/2} 
No ^{1}S_{0} 
Lr ^{2}P_{1/2}?  
Background color shows subcategory in the metal–metalloid–nonmetal trend:

Term symbols for an electron configuration
The process to calculate all possible term symbols for a given electron configuration is somewhat longer.
 First, the total number of possible microstates N is calculated for a given electron configuration. As before, the filled (sub)shells are discarded, and only the partially filled ones are kept. For a given orbital quantum number , t is the maximum allowed number of electrons, . If there are e electrons in a given subshell, the number of possible microstates is
 As an example, consider the carbon electron structure: 1s^{2}2s^{2}2p^{2}. After removing full subshells, there are 2 electrons in a plevel (), so there are
 different microstates.
 Second, all possible microstates are drawn. M_{L} and M_{S} for each microstate are calculated, with where m_{i} is either or for the ith electron, and M represents the resulting M_{L} or M_{S} respectively:
+1 0 −1 M_{L} M_{S} all up ↑ ↑ 1 1 ↑ ↑ 0 1 ↑ ↑ −1 1 all down ↓ ↓ 1 −1 ↓ ↓ 0 −1 ↓ ↓ −1 −1 one up
one down↑↓ 2 0 ↑ ↓ 1 0 ↑ ↓ 0 0 ↓ ↑ 1 0 ↑↓ 0 0 ↑ ↓ −1 0 ↓ ↑ 0 0 ↓ ↑ −1 0 ↑↓ −2 0  Third, the number of microstates for each M_{L}—M_{S} possible combination is counted:
M_{S} +1 0 −1 M_{L} +2 1 +1 1 2 1 0 1 3 1 −1 1 2 1 −2 1  Fourth, smaller tables can be extracted representing each possible term. Each table will have the size (2L+1) by (2S+1), and will contain only "1"s as entries. The first table extracted corresponds to M_{L} ranging from −2 to +2 (so L = 2), with a single value for M_{S} (implying S = 0). This corresponds to a ^{1}D term. The remaining terms fit inside the middle 3×3 portion of the table above. Then a second table can be extracted, removing the entries for M_{L} and M_{S} both ranging from −1 to +1 (and so S = L = 1, a ^{3}P term). The remaining table is a 1×1 table, with L = S = 0, i.e., a ^{1}S term.
S = 0, L = 2, J = 2
^{1}D_{2}M_{s} 0 +2 1 +1 1 0 1 −1 1 −2 1 S=1, L=1, J=2,1,0
^{3}P_{2}, ^{3}P_{1}, ^{3}P_{0}M_{s} +1 0 −1 +1 1 1 1 0 1 1 1 −1 1 1 1 S=0, L=0, J=0
^{1}S_{0}M_{s} 0 0 1  Fifth, applying Hund's rules, the ground state can be identified (or the lowest state for the configuration of interest.) Hund's rules should not be used to predict the order of states other than the lowest for a given configuration. (See examples at Hund's rules#Excited states.)
 If only two equivalent electrons are involved, there is an "Even Rule" which states that, for two equivalent electrons, the only states that are allowed are those for which the sum (L + S) is even.
Case of three equivalent electrons
 For three equivalent electrons (with the same orbital quantum number ), there is also a general formula (denoted by below) to count the number of any allowed terms with total orbital quantum number L and total spin quantum number S.
 where the floor function denotes the greatest integer not exceeding x.
 The detailed proof can be found in Renjun Xu's original paper.[5]
 For a general electronic configuration of , namely k equivalent electrons occupying one subshell, the general treatment and computer code can also be found in this paper.[5]
Alternative method using group theory
For configurations with at most two electrons (or holes) per subshell, an alternative and much quicker method of arriving at the same result can be obtained from group theory. The configuration 2p^{2} has the symmetry of the following direct product in the full rotation group:
 Γ^{(1)} × Γ^{(1)} = Γ^{(0)} + [Γ^{(1)}] + Γ^{(2)},
which, using the familiar labels Γ^{(0)} = S, Γ^{(1)} = P and Γ^{(2)} = D, can be written as
 P × P = S + [P] + D.
The square brackets enclose the antisymmetric square. Hence the 2p^{2} configuration has components with the following symmetries:
 S + D (from the symmetric square and hence having symmetric spatial wavefunctions);
 P (from the antisymmetric square and hence having an antisymmetric spatial wavefunction).
The Pauli principle and the requirement for electrons to be described by antisymmetric wavefunctions imply that only the following combinations of spatial and spin symmetry are allowed:
 ^{1}S + ^{1}D (spatially symmetric, spin antisymmetric)
 ^{3}P (spatially antisymmetric, spin symmetric).
Then one can move to step five in the procedure above, applying Hund's rules.
The group theory method can be carried out for other such configurations, like 3d^{2}, using the general formula
 Γ^{(j)} × Γ^{(j)} = Γ^{(2j)} + Γ^{(2j−2)} + ⋯ + Γ^{(0)} + [Γ^{(2j−1)} + ⋯ + Γ^{(1)}].
The symmetric square will give rise to singlets (such as ^{1}S, ^{1}D, & ^{1}G), while the antisymmetric square gives rise to triplets (such as ^{3}P & ^{3}F).
More generally, one can use
 Γ^{(j)} × Γ^{(k)} = Γ^{(j+k)} + Γ^{(j+k−1)} + ⋯ + Γ^{(j−k)}
where, since the product is not a square, it is not split into symmetric and antisymmetric parts. Where two electrons come from inequivalent orbitals, both a singlet and a triplet are allowed in each case.[6]
Summary of various coupling schemes and corresponding term symbols
Basic concepts for all coupling schemes:
 : individual orbital angular momentum vector for an electron, : individual spin vector for an electron, : individual total angular momentum vector for an electron, .
 : Total orbital angular momentum vector for all electrons in an atom ().
 : total spin vector for all electrons ().
 : total angular momentum vector for all electrons. The way the angular momenta are combined to form depends on the coupling scheme: for LS coupling, for jj coupling, etc.
 A quantum number corresponding to the magnitude of a vector is a letter without an arrow (ex: l is the orbital angular momentum quantum number for and )
 The parameter called multiplicity represents the number of possible values of the total angular momentum quantum number J for certain conditions.
 For a single electron, the term symbol is not written as S is always 1/2 and L is obvious from the orbital type.
 For two electron groups A and B with their own terms, each term may represent S, L and J which are quantum numbers corresponding to the , and vectors for each group. "Coupling" of terms A and B to form a new term C means finding quantum numbers for new vectors , and . This example is for LS coupling and which vectors are summed in a coupling is depending on which scheme of coupling is taken. Of course, the angular momentum addition rule is that where X can be s, l, j, S, L, J or any other angular momentummagnituderelated quantum number.
LS coupling (RussellSaunders coupling)
 Coupling scheme: and are calculated first then is obtained. In practical point of view, it means L, S and J are obtained by using addition rule of angular momentums with given electronics groups that are to be coupled.
 Electronic configuration + Term symbol: . is a Term which is from coupling of electrons in group. are principle quantum number, orbital quantum number and means there are N (equivalent) electrons in subshell. For , is equal to multiplicity, a number of possible values in J (final total angular momentum quantum number) from given S and L. For , multiplicity is but is still written in the Term symbol. Strictly speaking, is called Level and is called Term. Sometimes superscript o is attached to the Term, means the parity of group is odd ().
 Example:
 3d^{7} ^{4}F_{7/2}: ^{4}F_{7/2} is Level of 3d^{7} group in which are equivalent 7 electrons are in 3d subshell.
 3d^{7}(^{4}F)4s4p(^{3}P^{0}) ^{6}F^{0}
_{9/2}:[7] Terms are assigned for each group (with different principal quantum number n) and rightmost Level ^{6}F^{o}
_{9/2} is from coupling of Terms of these groups so ^{6}F^{o}
_{9/2} represents final total spin quantum number S, total orbital angular momentum quantum number L and total angular momentum quantum number J in this atomic energy level. The symbols ^{4}F and ^{3}P^{o} refer to seven and two electrons respectively so capital letters are used.  4f^{7}(^{8}S^{0})5d (^{7}D^{o})6p ^{8}F_{13/2}: There is a space between 5d and (^{7}D^{o}). It means (^{8}S^{0}) and 5d are coupled to get (^{7}D^{o}). Final level ^{8}F^{o}
_{13/2} is from coupling of (^{7}D^{o}) and 6p.  4f(^{2}F^{0}) 5d^{2}(^{1}G) 6s(^{2}G) ^{1}P^{0}
_{1}: There is only one Term ^{2}F^{o} which is isolated in the left of the leftmost space. It means (^{2}F^{o}) is coupled lastly; (^{1}G) and 6s are coupled to get (^{2}G) then (^{2}G) and (^{2}F^{o}) are coupled to get final Term ^{1}P^{o}
_{1}.
jj Coupling
 Coupling scheme: .
 Electronic configuration + Term symbol:
 Example:
 : There are two groups. One is and the other is . In , there are 2 electrons having in 6p subshell while there is an electron having in the same subshell in . Coupling of these two groups results in (coupling of j of three electrons).
 : in () is for 1st group and 2 in () is J_{2} for 2nd group . Subscript 11/2 of Term symbol is final J of .
J_{1}L_{2} coupling
 Coupling scheme: and .
 Electronic configuration + Term symbol: . For is equal to multiplicity, a number of possible values in J (final total angular momentum quantum number) from given S_{2} and K. For , multiplicity is but is still written in the Term symbol.
 Example:
 3p^{5}(^{2}P^{o}
_{1/2})5g ^{2}[9/2]^{o}
_{5}: . is K, which comes from coupling of J_{1} and l_{2}. Subscript 5 in Term symbol is J which is from coupling of K and s_{2}.  4f^{13}(^{2}F^{o}
_{7/2})5d^{2}(^{1}D) [7/2]^{o}
_{7/2}: . is K, which comes from coupling of J_{1} and L_{2}. Subscript in Term symbol is J which is from coupling of K and S_{2}.
 3p^{5}(^{2}P^{o}
LS_{1} coupling
 Coupling scheme:, .
 Electronic configuration + Term symbol: . For is equal to multiplicity, a number of possible values in J (final total angular momentum quantum number) from given S_{2} and K. For , multiplicity is but is still written in the Term symbol.
 Example:
 3d^{7}(^{4}P)4s4p(^{3}P^{o}) D^{o} ^{3}[5/2]^{o}
_{7/2}: . .
 3d^{7}(^{4}P)4s4p(^{3}P^{o}) D^{o} ^{3}[5/2]^{o}
Most famous coupling schemes are introduced here but these schemes can be mixed together to express energy state of atom. This summary is based on .
Racah notation and Paschen notation
These are notations for describing states of singly excited atoms, especially noble gas atoms. Racah notation is basically a combination of LS or Russell–Saunders coupling and J_{1}L_{2} coupling. LS coupling is for a parent ion and J_{1}L_{2} coupling is for a coupling of the parent ion and the excited electron. The parent ion is an unexcited part of the atom. For example, in Ar atom excited from a ground state ...3p^{6} to an excited state ...3p^{5}4p in electronic configuration, 3p^{5} is for the parent ion while 4p is for the excited electron.[8]
In Racah notation, states of excited atoms are denoted as . Quantities with a subscript 1 are for the parent ion, n and l are principal and orbital quantum numbers for the excited electron, K and J are quantum numbers for and where and are orbital angular momentum and spin for the excited electron respectively. “o” represents a parity of excited atom. For an inert (noble) gas atom, usual excited states are Np^{5}nl where N = 2, 3, 4, 5, 6 for Ne, Ar, Kr, Xe, Rn, respectively in order. Since the parent ion can only be ^{2}P_{1/2} or ^{2}P_{3/2}, the notation can be shortened to or , where nl means the parent ion is in ^{2}P_{3/2} while nl′ is for the parent ion in ^{2}P_{1/2} state.
Paschen notation is a somewhat odd notation; it is an old notation made to attempt to fit an emission spectrum of neon to a hydrogenlike theory. It has a rather simple structure to indicate energy levels of an excited atom. The energy levels are denoted as n′l#. l is just an orbital quantum number of the excited electron. n′l is written in a way that 1s for (n = N + 1, l = 0), 2p for (n = N + 1, l = 1), 2s for (n = N + 2, l = 0), 3p for (n = N + 2, l = 1), 3s for (n = N + 3, l = 0), etc. Rules of writing n′l from the lowest electronic configuration of the excited electron are: (1) l is written first, (2) n′ is consecutively written from 1 and the relation of l = n′ − 1, n′ − 2, ... , 0 (like a relation between n and l) is kept. n′l is an attempt to describe electronic configuration of the excited electron in a way of describing electronic configuration of hydrogen atom. # is an additional number denoted to each energy level of given n′l (there can be multiple energy levels of given electronic configuration, denoted by the term symbol). # denotes each level in order, for example, # = 10 is for a lower energy level than # = 9 level and # = 1 is for the highest level in a given n′l. An example of Paschen notation is below.
Electronic configuration of Neon  n′l  Electronic configuration of Argon  n′l 

1s^{2}2s^{2}2p^{6}  Ground state  [Ne]3s^{2}3p^{6}  Ground state 
1s^{2}2s^{2}2p^{5}3s^{1}  1s  [Ne]3s^{2}3p^{5}4s^{1}  1s 
1s^{2}2s^{2}2p^{5}3p^{1}  2p  [Ne]3s^{2}3p^{5}4p^{1}  2p 
1s^{2}2s^{2}2p^{5}4s^{1}  2s  [Ne]3s^{2}3p^{5}5s^{1}  2s 
1s^{2}2s^{2}2p^{5}4p^{1}  3p  [Ne]3s^{2}3p^{5}5p^{1}  3p 
1s^{2}2s^{2}2p^{5}5s^{1}  3s  [Ne]3s^{2}3p^{5}6s^{1}  3s 
Notes
 There is no official convention for naming angular momentum values greater than 20 (symbol Z). Many authors begin using Greek letters at this point (α, β, γ, ...). The occasions for which such notation is necessary are few and far between, however.
References
 NIST Atomic Spectrum Database To read neutral carbon atom levels for example, type "C I" in the Spectrum box and click on Retrieve data.
 H. N. Russell and F. A. Saunders, New Regularities in the Spectra of the Alkaline Earths, Astrophysical Journal, vol. 61, p. 38 (1925)
 Levine, Ira N., Quantum Chemistry (4th ed., PrenticeHall 1991), ISBN 0205127703
 "NIST Atomic Spectra Database Ionization Energies Form". NIST Physical Measurement Laboratory. National Institute of Standards and Technology (NIST). October 2018. Retrieved 28 January 2019.
This form provides access to NIST critically evaluated data on ground states and ionization energies of atoms and atomic ions.
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 "Atomic Spectroscopy  Different Coupling Scheme 9. Notations for Different Coupling Schemes". NIST Physical Measurement Laboratory. National Institute of Standards and Technology (NIST). 1 November 2017. Retrieved 31 January 2019.
 "APPENDIX 1  Coupling Schemes and Notation" (PDF). University of Toronto: Advanced Physics Laboratory  Course Homepage. Retrieved 5 Nov 2017.