Principal quantum number: Difference between revisions

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The '''principal quantum number''', usually designated by ''n'', appears in the description of the [[electron|electronic structure]] of [[atom]]s. The [[quantum number]] first arose in the [[Niels Bohr|Bohr]]-[[Arnold Sommerfeld|Sommerfeld]] theory of the hydrogen atom, but it is also part of the solution of the [[Schrödinger equation]] for [[hydrogen-like atom]]s. It is a positive integral number,  ''n'' = 1, 2, 3, …, that indexes  [[atomic shell]]s. Historically, atomic shells were indicated by the capital letters K, L, M, … for ''n=1,2,3,''…, respectively, but this usage is dying out.
The '''principal quantum number''', usually designated by ''n'', appears in the description of the [[electron|electronic structure]] of [[atom]]s. The [[quantum number]] first arose in the [[Niels Bohr|Bohr]]-[[Arnold Sommerfeld|Sommerfeld]] theory of the hydrogen atom, but it is also part of the solution of the [[Schrödinger equation]] for [[hydrogen-like atom]]s. It is a positive integer (''n'' = 1, 2, 3, …) that indexes  [[atomic shell]]s. Historically, atomic shells were indicated by the capital letters K, L, M, … for ''n=1,2,3,''…, respectively, but this usage is dying out.


In the Bohr-Sommerfeld ("old") quantum theory, the electron in a hydrogen-like (one-electron) atom moves in elliptic orbits. The principal quantum number appears in this theory at two places: in the energy ''E''<sub>''n''</sub> of the electron and in the length ''a''<sub>''n''</sub> of the major semiaxis of the ''n''th orbit,
In the Bohr-Sommerfeld ("old") quantum theory, the electron in a hydrogen-like (one-electron) atom moves in [[Ellipse|elliptic]] orbits. The principal quantum number appears in this theory at two places: in the energy ''E''<sub>''n''</sub> of the electron and in the length ''a''<sub>''n''</sub> of the semi-major axis of the ''n''th orbit,
:<math>
:<math>
E_n = -\frac{m_e}{2} \left( \frac{Z\,e^2}{4\pi\epsilon_0 \hbar \;n}\right)^2  
E_n = -\frac{m_e}{2} \left( \frac{Z\,e^2}{4\pi\epsilon_0 \hbar \;n}\right)^2  
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a_n =  \frac{4\pi \epsilon_0\; n^2 \hbar^2}{m_e \,Z\, e^2},
a_n =  \frac{4\pi \epsilon_0\; n^2 \hbar^2}{m_e \,Z\, e^2},
</math>
</math>
where Ry is the [[Rydberg constant|Rydberg energy]] for infinite nuclear mass (= 13.605&thinsp;6923 [[electronvolt|eV]]). Further, ''m''<sub>''e''</sub> is the mass of the electron, &minus;''e'' is the charge of the electron, ''Ze'' is the charge of the nucleus,  &epsilon;<sub>0</sub> is the [[electric constant]], and <math>\hbar</math> is [[Planck constant|Planck's reduced constant]].  
where Ry is the [[Rydberg constant|Rydberg energy]] for infinite nuclear mass (= 13.605&thinsp;6923 [[electronvolt|eV]]). Further, ''m''<sub>''e''</sub> is the mass of the electron, &minus;''e'' is the charge of the electron, ''Ze'' is the charge of the nucleus,  &epsilon;<sub>0</sub> is the [[electric constant]], and <math>\hbar=h/2\pi</math> is [[Planck constant|Planck's reduced constant]].  


In the "new" [[quantum mechanics]] (of [[Heisenberg]], [[Schrödinger]], and others) the energy ''E''<sub>''n''</sub> of a bound electron in a hydrogen-like atom satisfies the exact same equation, but the electron ''orbit'' is replaced by an [[atomic orbital|electron ''orbital'']];  the latter has no radius. However, in the new quantum theory the same expression for ''a''<sub>''n''</sub> appears in the form of the [[expectation value]] of ''r'' (the length of the position vector of the electron) with respect to a state with principal quantum number ''n''. That is, quantum mechanics gives the same measure for the "size" of a one-electron atom  (in state ''n'') as the old quantum theory.
In the "new" [[quantum mechanics]] (of [[Heisenberg]], [[Schrödinger]], and others) the energy ''E''<sub>''n''</sub> of a bound electron in a hydrogen-like atom satisfies the exact same equation, but the electron ''orbit'' is replaced by an [[atomic orbital|electron ''orbital'']];  the latter has no radius. However, in the new quantum theory the same expression for ''a''<sub>''n''</sub> appears in the form of the [[expectation value]] of ''r'' (the length of the position vector of the electron) with respect to a state with principal quantum number ''n''. That is, quantum mechanics gives the same measure for the "size" of a one-electron atom  (in state ''n'') as the old quantum theory.
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==Azimuthal and magnetic quantum numbers==
==Azimuthal and magnetic quantum numbers==
An atomic shell consists of [[atomic subshell]]s that are labeled by the ''azimuthal quantum number'', commonly denoted by ''ℓ''. The azimuthal quantum number is more often referred to as ''angular momentum quantum number'', because the eigenvalues of the squared orbital [[angular momentum (quantum)|angular momentum]] operator <font style="vertical-align: top;"><math>\hat{l}^2</math></font> are equal to <math>\ell(\ell+1)\;\hbar^2</math>.  
An atomic shell consists of [[atomic subshell]]s that are labeled by the ''azimuthal quantum number'', commonly denoted by ''ℓ''. The azimuthal quantum number is more often referred to as ''angular momentum quantum number'', because the eigenvalues of the squared orbital [[angular momentum (quantum)|angular momentum]] operator <font style="vertical-align: top;"><math>\hat{l}^2</math></font> are equal to ''ℓ''(''ℓ''+1) ℏ&sup2;.


For a given atomic shell of principal quantum number ''n'', ''ℓ'' runs from 0 to ''n''&minus;1, as follows from  the solution of the Schrödinger equation.  In total, an atomic shell with quantum number ''n'' consists of ''n'' subshells and has
For a given atomic shell of principal quantum number ''n'', ''ℓ'' runs from 0 to ''n''&minus;1, as follows from  the solution of the Schrödinger equation.  In total, an atomic shell with quantum number ''n'' consists of ''n'' subshells and has
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</math>
</math>
spatial (i.e., function of the position vector of the electron) atomic orbitals.  
spatial (i.e., function of the position vector of the electron) atomic orbitals.  
An atomic subshell consists of 2''ℓ''+1 [[atomic orbital]]s labeled by the ''orbital magnetic quantum number'', almost invariably denoted by ''m''. For given ''ℓ'', ''m'' runs over 2''ℓ''+1 values: ''m'' = &minus;''ℓ'', &minus;''ℓ''+1,  &hellip;, ''ℓ''&minus;1, ''ℓ''. The number ''m'' is proportional to the eigenvalues of the ''z''-component of the orbital angular momentum operator <font style="vertical-align: top;"><math>\hat{l}_z</math></font> that has eigenvalues <font style="vertical-align: text-top;"><math>m\hbar</math></font>.
An atomic subshell consists of 2''ℓ''+1 [[atomic orbital]]s labeled by the ''orbital magnetic quantum number'', almost invariably denoted by ''m''. For given ''ℓ'', ''m'' runs over 2''ℓ''+1 values: ''m'' = &minus;''ℓ'', &minus;''ℓ''+1,  &hellip;, ''ℓ''&minus;1, ''ℓ''. The number ''m'' is proportional to the eigenvalues of the ''z''-component of the orbital angular momentum operator <font style="vertical-align: top;"><math>\hat{l}_z</math></font> that has eigenvalues ''m''ℏ.  


For historical reasons the orbitals of certain azimuthal quantum number ''ℓ'' are denoted by letters:
For historical reasons the orbitals of certain azimuthal quantum number ''ℓ'' are denoted by letters:
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Any spatial atomic orbital can be occupied at most twice, which is because the ''spin  magnetic  quantum number'' ''m''<sub>s</sub> (proportional to the eigenvalues of the ''z''-component of the spin angular momentum operator <math>\hat{s}_z\,</math>)  can have only two values: +&frac12; (spin up) and &minus;&frac12; (spin down). In addition, the [[Pauli exclusion principle]] states that no two electrons with the same four quantum numbers ''n'', ''ℓ'', ''m'', and ''m''<sub>s</sub> can occupy the same atomic orbital. As a consequence,  the spatial orbital (''n'',''ℓ'',''m'') can be occupied at most by two electrons with spin ''m''<sub>s</sub> = &plusmn;&frac12;.  
Any spatial atomic orbital can be occupied at most twice, which is because the ''spin  magnetic  quantum number'' ''m''<sub>s</sub> (proportional to the eigenvalues of the ''z''-component of the spin angular momentum operator <math>\hat{s}_z\,</math>)  can have only two values: +&frac12; (spin up) and &minus;&frac12; (spin down). In addition, the [[Pauli exclusion principle]] states that no two electrons with the same four quantum numbers ''n'', ''ℓ'', ''m'', and ''m''<sub>s</sub> can occupy the same atomic orbital. As a consequence,  the spatial orbital (''n'',''ℓ'',''m'') can be occupied at most by two electrons with spin ''m''<sub>s</sub> = &plusmn;&frac12;.  
Hence a subshell can accommodate at most 2(2''l''+1) electrons.  If a subshell accommodates the maximum number of electrons, it  is called ''closed''.  If the atomic shell ''n'' contains the maximum of 2''n''<sup>2</sup> electrons, it is also called ''closed''. For instance the noble gas [[neon]] in its lowest energy state has the [[electron configuration]] (1''s'')<sup>''2''</sup>(2''s'')<sup>''2''</sup>(2''p'')<sup>''6''</sup>, that is, all its shells and subshells are closed.
Hence a subshell can accommodate at most 2(2''l''+1) electrons.  If a subshell accommodates the maximum number of electrons, it  is called ''closed''.  If the atomic shell ''n'' contains the maximum of 2''n''<sup>2</sup> electrons, it is also called ''closed''. For instance the noble gas [[neon]] in its lowest energy state has the [[electron configuration]] (1''s'')<sup>''2''</sup>(2''s'')<sup>''2''</sup>(2''p'')<sup>''6''</sup>, that is, all its shells and subshells are closed.[[Category:Suggestion Bot Tag]]

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The principal quantum number, usually designated by n, appears in the description of the electronic structure of atoms. The quantum number first arose in the Bohr-Sommerfeld theory of the hydrogen atom, but it is also part of the solution of the Schrödinger equation for hydrogen-like atoms. It is a positive integer (n = 1, 2, 3, …) that indexes atomic shells. Historically, atomic shells were indicated by the capital letters K, L, M, … for n=1,2,3,…, respectively, but this usage is dying out.

In the Bohr-Sommerfeld ("old") quantum theory, the electron in a hydrogen-like (one-electron) atom moves in elliptic orbits. The principal quantum number appears in this theory at two places: in the energy En of the electron and in the length an of the semi-major axis of the nth orbit,

where Ry is the Rydberg energy for infinite nuclear mass (= 13.605 6923 eV). Further, me is the mass of the electron, −e is the charge of the electron, Ze is the charge of the nucleus, ε0 is the electric constant, and is Planck's reduced constant.

In the "new" quantum mechanics (of Heisenberg, Schrödinger, and others) the energy En of a bound electron in a hydrogen-like atom satisfies the exact same equation, but the electron orbit is replaced by an electron orbital; the latter has no radius. However, in the new quantum theory the same expression for an appears in the form of the expectation value of r (the length of the position vector of the electron) with respect to a state with principal quantum number n. That is, quantum mechanics gives the same measure for the "size" of a one-electron atom (in state n) as the old quantum theory.

Strictly speaking, the principal quantum number is not defined for many-electron atoms. However, in a fairly good approximate description (central field plus independent-particle model) of the many-electron atom, the principal quantum number does appear and hence n is a label that is often applied to many-electron atoms as well.

Azimuthal and magnetic quantum numbers

An atomic shell consists of atomic subshells that are labeled by the azimuthal quantum number, commonly denoted by . The azimuthal quantum number is more often referred to as angular momentum quantum number, because the eigenvalues of the squared orbital angular momentum operator are equal to (+1) ℏ².

For a given atomic shell of principal quantum number n, runs from 0 to n−1, as follows from the solution of the Schrödinger equation. In total, an atomic shell with quantum number n consists of n subshells and has

spatial (i.e., function of the position vector of the electron) atomic orbitals. An atomic subshell consists of 2+1 atomic orbitals labeled by the orbital magnetic quantum number, almost invariably denoted by m. For given , m runs over 2+1 values: m = −, −+1, …, −1, . The number m is proportional to the eigenvalues of the z-component of the orbital angular momentum operator that has eigenvalues mℏ.

For historical reasons the orbitals of certain azimuthal quantum number are denoted by letters: s, p, d, f, g, for = 0, 1, 2, 3, 4, respectively. For instance an atomic orbital with n = 4 and = 2 is written as 4d. If the n = 4, = 2 subshell is occupied k times (there are k electrons in the 4d orbital), we indicate this by writing (4d)k.

Any spatial atomic orbital can be occupied at most twice, which is because the spin magnetic quantum number ms (proportional to the eigenvalues of the z-component of the spin angular momentum operator ) can have only two values: +½ (spin up) and −½ (spin down). In addition, the Pauli exclusion principle states that no two electrons with the same four quantum numbers n, , m, and ms can occupy the same atomic orbital. As a consequence, the spatial orbital (n,,m) can be occupied at most by two electrons with spin ms = ±½. Hence a subshell can accommodate at most 2(2l+1) electrons. If a subshell accommodates the maximum number of electrons, it is called closed. If the atomic shell n contains the maximum of 2n2 electrons, it is also called closed. For instance the noble gas neon in its lowest energy state has the electron configuration (1s)2(2s)2(2p)6, that is, all its shells and subshells are closed.