A molecular orbital diagram, or MO diagram, is a qualitative descriptive tool explaining chemical bonding in molecules in terms of molecular orbital theory in general and the linear combination of atomic orbitals (LCAO) method in particular. A fundamental principle of these theories is that as atoms bond to form molecules, a certain number of atomic orbitals combine to form the same number of molecular orbitals, although the electrons involved may be redistributed among the orbitals. This tool is very well suited for simple diatomic molecules such as dihydrogen, dioxygen, and carbon monoxide but becomes more complex when discussing even comparatively simple polyatomic molecules, such as methane. MO diagrams can explain why some molecules exist and others do not. They can also predict bond strength, as well as the electronic transitions that can take place.
Qualitative MO theory was introduced in 1928 by Robert S. Mulliken and Friedrich Hund. A mathematical description was provided by contributions from Douglas Hartree in 1928 and Vladimir Fock in 1930.
Molecular orbital diagrams are diagrams of molecular orbital (MO) energy levels, shown as short horizontal lines in the center, flanked by constituent atomic orbital (AO) energy levels for comparison, with the energy levels increasing from the bottom to the top. Lines, often dashed diagonal lines, connect MO levels with their constituent AO levels. Degenerate energy levels are commonly shown side by side. Appropriate AO and MO levels are filled with electrons by the Pauli Exclusion Principle, symbolized by small vertical arrows whose directions indicate the electron spins. The AO or MO shapes themselves are often not shown on these diagrams. For a diatomic molecule, an MO diagram effectively shows the energetics of the bond between the two atoms, whose AO unbonded energies are shown on the sides. For simple polyatomic molecules with a "central atom" such as methane () or carbon dioxide (), a MO diagram may show one of the identical bonds to the central atom. For other polyatomic molecules, an MO diagram may show one or more bonds of interest in the molecules, leaving others out for simplicity. Often even for simple molecules, AO and MO levels of inner orbitals and their electrons may be omitted from a diagram for simplicity.
In MO theory molecular orbitals form by the overlap of atomic orbitals. Because ÃÂ bonds feature greater overlap than ÃÂ bonds, ÃÂ bonding and ÃÂ* antibonding orbitals feature greater energy splitting (separation) than ÃÂ and ÃÂ* orbitals. The atomic orbital energy correlates with electronegativity as more electronegative atoms hold their electrons more tightly, lowering their energies. Sharing of molecular orbitals between atoms is more important when the atomic orbitals have comparable energy; when the energies differ greatly the orbitals tend to be localized on one atom and the mode of bonding becomes ionic. A second condition for overlapping atomic orbitals is that they have the same symmetry.
Two atomic orbitals can overlap in two ways depending on their phase relationship (or relative signs for real orbitals). The phase (or sign) of an orbital is a direct consequence of the wave-like properties of electrons. In graphical representations of orbitals, orbital phase is depicted either by a plus or minus sign (which has no relationship to electric charge) or by shading one lobe. The sign of the phase itself does not have physical meaning except when mixing orbitals to form molecular orbitals.
Two same-sign orbitals have a constructive overlap forming a molecular orbital with the bulk of the electron density located between the two nuclei. This MO is called the bonding orbital and its energy is lower than that of the original atomic orbitals. A bond involving molecular orbitals which are symmetric with respect to any rotation around the bond axis is called a sigma bond (ÃÂ-bond). If the phase cycles once while rotating round the axis, the bond is a pi bond (ÃÂ-bond). Symmetry labels are further defined by whether the orbital maintains its original character after an inversion about its center; if it does, it is defined gerade, g. If the orbital does not maintain its original character, it is ungerade, u.
Atomic orbitals can also interact with each other out-of-phase which leads to destructive cancellation and no electron density between the two nuclei at the so-called nodal plane depicted as a perpendicular dashed line. In this anti-bonding MO with energy much higher than the original AO's, any electrons present are located in lobes pointing away from the central internuclear axis. For a corresponding ÃÂ-bonding orbital, such an orbital would be symmetrical but differentiated from it by an asterisk as in ÃÂ*. For a ÃÂ-bond, corresponding bonding and antibonding orbitals would not have such symmetry around the bond axis and be designated ÃÂ and ÃÂ*, respectively.
The next step in constructing an MO diagram is filling the newly formed molecular orbitals with electrons. Three general rules apply:
The filled MO highest in energy is called the highest occupied molecular orbital (HOMO) and the empty MO just above it is then the lowest unoccupied molecular orbital (LUMO). The electrons in the bonding MO's are called bonding electrons and any electrons in the antibonding orbital would be called antibonding electrons. The reduction in energy of these electrons is the driving force for chemical bond formation. Whenever mixing for an atomic orbital is not possible for reasons of symmetry or energy, a non-bonding MO is created, which is often quite similar to and has energy level equal or close to its constituent AO, thus not contributing to bonding energetics. The resulting electron configuration can be described in terms of bond type, parity and occupancy for example dihydrogen 1ÃÂ<sub>g</sub><sup>2</sup>. Alternatively it can be written as a molecular term symbol e.g. <sup>1</sup>ã<sub>g</sub><sup>+</sup> for dihydrogen. Sometimes, the letter n is used to designate a non-bonding orbital.
For a stable bond, the bond order defined as
must be positive.
The relative order in MO energies and occupancy corresponds with electronic transitions found in photoelectron spectroscopy (PES). In this way it is possible to experimentally verify MO theory. In general, sharp PES transitions indicate nonbonding electrons and broad bands are indicative of bonding and antibonding delocalized electrons. Bands can resolve into fine structure with spacings corresponding to vibrational modes of the molecular cation (see FranckâÂÂCondon principle). PES energies are different from ionisation energies which relates to the energy required to strip off the th electron after the first electrons have been removed. MO diagrams with energy values can be obtained mathematically using the HartreeâÂÂFock method. The starting point for any MO diagram is a predefined molecular geometry for the molecule in question. An exact relationship between geometry and orbital energies is given in Walsh diagrams.
The phenomenon of s-p mixing occurs when molecular orbitals of the same symmetry formed from the combination of 2s and 2p atomic orbitals are close enough in energy to further interact, which can lead to a change in the expected order of orbital energies. When molecular orbitals are formed, they are mathematically obtained from linear combinations of the starting atomic orbitals. Generally, in order to predict their relative energies, it is sufficient to consider only one atomic orbital from each atom to form a pair of molecular orbitals, as the contributions from the others are negligible. For instance, in dioxygen the 3ÃÂ<sub>g</sub> MO can be roughly considered to be formed from interaction of oxygen 2p<sub>z</sub> AOs only. It is found to be lower in energy than the 1ÃÂ<sub>u</sub> MO, both experimentally and from more sophisticated computational models, so that the expected order of filling is the 3ÃÂ<sub>g</sub> before the 1ÃÂ<sub>u</sub>. Hence the approximation to ignore the effects of further interactions is valid. However, experimental and computational results for homonuclear diatomics from Li<sub>2</sub> to N<sub>2</sub> and certain heteronuclear combinations such as CO and NO show that the 3ÃÂ<sub>g</sub> MO is higher in energy than (and therefore filled after) the 1ÃÂ<sub>u</sub> MO. This can be rationalised as the first-approximation 3ÃÂ<sub>g</sub> has a suitable symmetry to interact with the 2ÃÂ<sub>g</sub> bonding MO formed from the 2s AOs. As a result, the 2ÃÂ<sub>g</sub> is lowered in energy, whilst the 3ÃÂ<sub>g</sub> is raised. For the aforementioned molecules this results in the 3ÃÂ<sub>g</sub> being higher in energy than the 1ÃÂ<sub>u</sub> MO, which is where s-p mixing is most evident. Likewise, interaction between the 2ÃÂ<sub>u</sub>* and 3ÃÂ<sub>u</sub>* MOs leads to a lowering in energy of the former and a raising in energy of the latter. However this is of less significance than the interaction of the bonding MOs.
A diatomic molecular orbital diagram is used to understand the bonding of a diatomic molecule. MO diagrams can be used to deduce magnetic properties of a molecule and how they change with ionization. They also give insight to the bond order of the molecule, how many bonds are shared between the two atoms.
The energies of the electrons are further understood by applying the Schrödinger equation to a molecule. Quantum Mechanics is able to describe the energies exactly for single electron systems but can be approximated precisely for multiple electron systems using the Born-Oppenheimer Approximation, such that the nuclei are assumed stationary. The LCAO-MO method is used in conjunction to further describe the state of the molecule.
Diatomic molecules consist of a bond between only two atoms. They can be broken into two categories: homonuclear and heteronuclear. A homonuclear diatomic molecule is one composed of two atoms of the same element. Examples are H<sub>2</sub>, O<sub>2</sub>, and N<sub>2</sub>. A heteronuclear diatomic molecule is composed of two atoms of two different elements. Examples include CO, HCl, and NO.
The smallest molecule, hydrogen gas exists as dihydrogen (H-H) with a single covalent bond between two hydrogen atoms. As each hydrogen atom has a single 1s atomic orbital for its electron, the bond forms by overlap of these two atomic orbitals. In the figure the two atomic orbitals are depicted on the left and on the right. The vertical axis always represents the orbital energies. Each atomic orbital is singly occupied with an up or down arrow representing an electron.
Application of MO theory for dihydrogen results in having both electrons in the bonding MO with electron configuration 1ÃÂ<sub>g</sub><sup>2</sup>. The bond order for dihydrogen is (2-0)/2 = 1. The photoelectron spectrum of dihydrogen shows a single set of multiplets between 16 and 18 eV (electron volts).
The dihydrogen MO diagram helps explain how a bond breaks. When applying energy to dihydrogen, a molecular electronic transition takes place when one electron in the bonding MO is promoted to the antibonding MO. The result is that there is no longer a net gain in energy.
The superposition of the two 1s atomic orbitals leads to the formation of the ÃÂ and ÃÂ* molecular orbitals. Two atomic orbitals in phase create a larger electron density, which leads to the ÃÂ orbital. If the two 1s orbitals are not in phase, a node between them causes a jump in energy, the ÃÂ* orbital. From the diagram you can deduce the bond order, how many bonds are formed between the two atoms. For this molecule it is equal to one. Bond order can also give insight to how close or stretched a bond has become if a molecule is ionized.
Dihelium (He-He) is a hypothetical molecule and MO theory helps to explain why dihelium does not exist in nature. The MO diagram for dihelium looks very similar to that of dihydrogen, but each helium has two electrons in its 1s atomic orbital rather than one for hydrogen, so there are now four electrons to place in the newly formed molecular orbitals.
The only way to accomplish this is by occupying both the bonding and antibonding orbitals with two electrons, which reduces the bond order ((2âÂÂ2)/2) to zero and cancels the net energy stabilization. However, by removing one electron from dihelium, the stable gas-phase species ion is formed with bond order 1/2.
Another molecule that is precluded based on this principle is diberyllium. Beryllium has an electron configuration 1s<sup>2</sup>2s<sup>2</sup>, so there are again two electrons in the valence level. However, the 2s can mix with the 2p orbitals in diberyllium, whereas there are no p orbitals in the valence level of hydrogen or helium. This mixing makes the antibonding 1ÃÂ<sub>u</sub> orbital slightly less antibonding than the bonding 1ÃÂ<sub>g</sub> orbital is bonding, with a net effect that the whole configuration has a slight bonding nature. This explains the fact that the diberyllium molecule exists and has been observed in the gas phase. The slight bonding nature explains the low dissociation energy of only 59 kJ÷mol<sup>âÂÂ1</sup>.
MO theory correctly predicts that dilithium is a stable molecule with bond order 1 (configuration 1ÃÂ<sub>g</sub><sup>2</sup>1ÃÂ<sub>u</sub><sup>2</sup>2ÃÂ<sub>g</sub><sup>2</sup>). The 1s MOs are completely filled and do not participate in bonding.
Dilithium is a gas-phase molecule with a much lower bond strength than dihydrogen because the 2s electrons are further removed from the nucleus. In a more detailed analysis which considers the environment of each orbital due to all other electrons, both the 1ÃÂ orbitals have higher energies than the 1s AO and the occupied 2ÃÂ is also higher in energy than the 2s AO (see table 1).
The MO diagram for diboron (B-B, electron configuration 1ÃÂ<sub>g</sub><sup>2</sup>1ÃÂ<sub>u</sub><sup>2</sup>2ÃÂ<sub>g</sub><sup>2</sup>2ÃÂ<sub>u</sub><sup>2</sup>1ÃÂ<sub>u</sub><sup>2</sup>) requires the introduction of an atomic orbital overlap model for p orbitals. The three dumbbell-shaped p-orbitals have equal energy and are oriented mutually perpendicularly (or orthogonally). The p-orbitals oriented in the z-direction (p<sub>z</sub>) can overlap end-on forming a bonding (symmetrical) ÃÂ orbital and an antibonding ÃÂ* molecular orbital. In contrast to the sigma 1s MO's, the ÃÂ 2p has some non-bonding electron density at either side of the nuclei and the ÃÂ* 2p has some electron density between the nuclei.
The other two p-orbitals, p<sub>y</sub> and p<sub>x</sub>, can overlap side-on. The resulting bonding orbital has its electron density in the shape of two lobes above and below the plane of the molecule. The orbital is not symmetric around the molecular axis and is therefore a pi orbital. The antibonding pi orbital (also asymmetrical) has four lobes pointing away from the nuclei. Both p<sub>y</sub> and p<sub>x</sub> orbitals form a pair of pi orbitals equal in energy (degenerate) and can have higher or lower energies than that of the sigma orbital.
In diboron the 1s and 2s electrons do not participate in bonding but the single electrons in the 2p orbitals occupy the 2ÃÂp<sub>y</sub> and the 2ÃÂp<sub>x</sub> MO's resulting in bond order 1. Because the electrons have equal energy (they are degenerate) diboron is a diradical and since the spins are parallel the molecule is paramagnetic.
In certain diborynes the boron atoms are excited and the bond order is 3.
Like diboron, dicarbon (C-C electron configuration:1ÃÂ<sub>g</sub><sup>2</sup>1ÃÂ<sub>u</sub><sup>2</sup>2ÃÂ<sub>g</sub><sup>2</sup>2ÃÂ<sub>u</sub><sup>2</sup>1ÃÂ<sub>u</sub><sup>4</sup>) is a reactive gas-phase molecule. The molecule can be described as having two pi bonds but without a sigma bond.
With nitrogen, we see the two molecular orbitals mixing and the energy repulsion. This is the reasoning for the rearrangement from a more familiar diagram. The ÃÂ from the 2p is more non-bonding due to mixing, and same with the 2s ÃÂ. This also causes a large jump in energy in the 2p ÃÂ* orbital. The bond order of diatomic nitrogen is three, and it is a diamagnetic molecule.
The bond order for dinitrogen (1ÃÂ<sub>g</sub><sup>2</sup>1ÃÂ<sub>u</sub><sup>2</sup>2ÃÂ<sub>g</sub><sup>2</sup>2ÃÂ<sub>u</sub><sup>2</sup>1ÃÂ<sub>u</sub><sup>4</sup>3ÃÂ<sub>g</sub><sup>2</sup>) is three because two electrons are now also added in the 3ÃÂ MO. The MO diagram correlates with the experimental photoelectron spectrum for nitrogen. The 1ÃÂ electrons can be matched to a peak at 410 eV (broad), the 2ÃÂ<sub>g</sub> electrons at 37 eV (broad), the 2ÃÂ<sub>u</sub> electrons at 19 eV (doublet), the 1ÃÂ<sub>u</sub><sup>4</sup> electrons at 17 eV (multiplets), and finally the 3ÃÂ<sub>g</sub><sup>2</sup> at 15.5 eV (sharp).
Oxygen has a similar setup to H<sub>2</sub>, but now we consider 2s and 2p orbitals. When creating the molecular orbitals from the p orbitals, the three atomic orbitals split into three molecular orbitals, a singly degenerate ÃÂ and a doubly degenerate ÃÂ orbital. Another property we can observe by examining molecular orbital diagrams is the magnetic property of diamagnetic or paramagnetic. If all the electrons are paired, there is a slight repulsion and it is classified as diamagnetic. If unpaired electrons are present, it is attracted to a magnetic field, and therefore paramagnetic. Oxygen is an example of a paramagnetic diatomic. The bond order of diatomic oxygen is two.
MO treatment of dioxygen is different from that of the previous diatomic molecules because the pÃÂ MO is now lower in energy than the 2ÃÂ orbitals. This is attributed to interaction between the 2s MO and the 2p<sub>z</sub> MO. Distributing 8 electrons over 6 molecular orbitals leaves the final two electrons as a degenerate pair in the 2pÃÂ* antibonding orbitals resulting in a bond order of 2. As in diboron, these two unpaired electrons have the same spin in the ground state, which is a paramagnetic diradical triplet oxygen. The first excited state has both HOMO electrons paired in one orbital with opposite spins, and is known as singlet oxygen.
The bond order decreases and the bond length increases in the order (112.2 pm), (121 pm), (128 pm) and (149 pm).
In difluorine two additional electrons occupy the 2pÃÂ* with a bond order of 1. In dineon (as with dihelium) the number of bonding electrons equals the number of antibonding electrons and this molecule does not exist.
Dimolybdenum (Mo<sub>2</sub>) is notable for having a sextuple bond. This involves two sigma bonds (4d<sub>z<sup>2</sup></sub> and 5s), two pi bonds (using 4d<sub>xz</sub> and 4d<sub>yz</sub>), and two delta bonds (4d<sub>x<sup>2</sup> â y<sup>2</sup></sub> and 4d<sub>xy</sub>). Ditungsten (W<sub>2</sub>) has a similar structure.
Table 1 gives an overview of MO energies for first row diatomic molecules calculated by the Hartree-Fock-Roothaan method, together with atomic orbital energies.
In heteronuclear diatomic molecules, mixing of atomic orbitals only occurs when the electronegativity values are similar. In carbon monoxide (CO, isoelectronic with dinitrogen) the oxygen 2s orbital is much lower in energy than the carbon 2s orbital and therefore the degree of mixing is low. The electron configuration 1ÃÂ<sup>2</sup>1ÃÂ*<sup>2</sup>2ÃÂ<sup>2</sup>2ÃÂ*<sup>2</sup>1ÃÂ<sup>4</sup>3ÃÂ<sup>2</sup> is identical to that of nitrogen. The g and u subscripts no longer apply because the molecule lacks a center of symmetry.
In hydrogen fluoride (HF), the hydrogen 1s orbital can mix with fluorine 2p<sub>z</sub> orbital to form a sigma bond because experimentally the energy of 1s of hydrogen is comparable with 2p of fluorine. The HF electron configuration 1ÃÂ<sup>2</sup>2ÃÂ<sup>2</sup>3ÃÂ<sup>2</sup>1ÃÂ<sup>4</sup> reflects that the other electrons remain in three lone pairs and that the bond order is 1.
The more electronegative atom is the more energetically excited because it more similar in energy to its atomic orbital. This also accounts for the majority of the electron negativity residing around the more electronegative molecule. Applying the LCAO-MO method allows us to move away from a more static Lewis structure type approach and actually account for periodic trends that influence electron movement. Non-bonding orbitals refer to lone pairs seen on certain atoms in a molecule. A further understanding for the energy level refinement can be acquired by delving into quantum chemistry; the Schrödinger equation can be applied to predict movement and describe the state of the electrons in a molecule.
Nitric oxide is a heteronuclear molecule that exhibits mixing. The construction of its MO diagram is the same as for the homonuclear molecules. It has a bond order of 2.5 and is a paramagnetic molecule. The energy differences of the 2s orbitals are different enough that each produces its own non-bonding ÃÂ orbitals. Notice this is a good example of making the ionized NO<sup>+</sup> stabilize the bond and generate a triple bond, also changing the magnetic property to diamagnetic.
Hydrogen fluoride is another example of a heteronuclear molecule. It is slightly different in that the ÃÂ orbital is non-bonding, as well as the 2s ÃÂ. From the hydrogen, its valence 1s electron interacts with the 2p electrons of fluorine. This molecule is diamagnetic and has a bond order of one.
Carbon dioxide, , is a linear molecule with a total of sixteen bonding electrons in its valence shell. Carbon is the central atom of the molecule and a principal axis, the z-axis, is visualized as a single axis that goes through the center of carbon and the two oxygens atoms. For convention, blue atomic orbital lobes are positive phases, red atomic orbitals are negative phases, with respect to the wave function from the solution of the Schrödinger equation. In carbon dioxide the carbon 2s (âÂÂ19.4 eV), carbon 2p (âÂÂ10.7 eV), and oxygen 2p (âÂÂ15.9 eV)) energies associated with the atomic orbitals are in proximity whereas the oxygen 2s energy (âÂÂ32.4 eV) is different.
Carbon and each oxygen atom will have a 2s atomic orbital and a 2p atomic orbital, where the p orbital is divided into p<sub>x</sub>, p<sub>y</sub>, and p<sub>z</sub>. With these derived atomic orbitals, symmetry labels are deduced with respect to rotation about the principal axis which generates a phase change, pi bond (ÃÂ) or generates no phase change, known as a sigma bond (ÃÂ). Symmetry labels are further defined by whether the atomic orbital maintains its original character after an inversion about its center atom; if the atomic orbital does retain its original character it is defined gerade, g, or if the atomic orbital does not maintain its original character, ungerade, u. The final symmetry-labeled atomic orbital is now known as an irreducible representation.
Carbon dioxideâÂÂs molecular orbitals are made by the linear combination of atomic orbitals of the same irreducible representation that are also similar in atomic orbital energy. Significant atomic orbital overlap explains why sp bonding may occur. Strong mixing of the oxygen 2s atomic orbital is not to be expected and are non-bonding degenerate molecular orbitals. The combination of similar atomic orbital/wave functions and the combinations of atomic orbital/wave function inverses create particular energies associated with the nonbonding (no change), bonding (lower than either parent orbital energy) and antibonding (higher energy than either parent atomic orbital energy) molecular orbitals.
For nonlinear molecules, the orbital symmetries are not àor àbut depend on the symmetry of each molecule. Water () is a bent molecule (105ð) with C<sub>2v</sub> molecular symmetry. The possible orbital symmetries are listed in the table below. For example, an orbital of B<sub>1</sub> symmetry (called a b<sub>1</sub> orbital with a small b since it is a one-electron function) is multiplied by -1 under the symmetry operations C<sub>2</sub> (rotation about the 2-fold rotation axis) and ÃÂ<sub>v</sub>'(yz) (reflection in the molecular plane). It is multiplied by +1(unchanged) by the identity operation E and by ÃÂ<sub>v</sub>(xz) (reflection in the plane bisecting the H-O-H angle).
The oxygen atomic orbitals are labeled according to their symmetry as a<sub>1</sub> for the 2s orbital and b<sub>1</sub> (2p<sub>x</sub>), b<sub>2</sub> (2p<sub>y</sub>) and a<sub>1</sub> (2p<sub>z</sub>) for the three 2p orbitals. The two hydrogen 1s orbitals are premixed to form a<sub>1</sub> (ÃÂ) and b<sub>2</sub> (ÃÂ*) MO.
Mixing takes place between same-symmetry orbitals of comparable energy resulting a new set of MO's for water:
In agreement with this description the photoelectron spectrum for water shows a sharp peak for the nonbonding 1b<sub>1</sub> MO (12.6 eV) and three broad peaks for the 3a<sub>1</sub> MO (14.7 eV), 1b<sub>2</sub> MO (18.5 eV) and the 2a<sub>1</sub> MO (32.2 eV). The 1b<sub>1</sub> MO is a lone pair, while the 3a<sub>1</sub>, 1b<sub>2</sub> and 2a<sub>1</sub> MO's can be localized to give two OâÂÂH bonds and an in-plane lone pair. This MO treatment of water does not have two equivalent rabbit ear lone pairs.
Hydrogen sulfide (H<sub>2</sub>S) too has a C<sub>2v</sub> symmetry with 8 valence electrons but the bending angle is only 92ð. As reflected in its photoelectron spectrum as compared to water the 5a<sub>1</sub> MO (corresponding to the 3a<sub>1</sub> MO in water) is stabilised (improved overlap) and the 2b<sub>2</sub> MO (corresponding to the 1b<sub>2</sub> MO in water) is destabilized (poorer overlap).