Rotational spectroscopy

Rotational spectroscopy
This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Rotational_spectroscopy".

Part of the rotational spectrum of HCl Gas, showing the presence of P- and R- branches. Frequency is on the x-axis, and transmittance on the y-axis.

Rotational spectroscopy or microwave spectroscopy studies the absorption and emission electromagnetic radiation (typically in the microwave region of the electromagnetic spectrum) by molecules associated with a corresponding change in the rotational quantum number of the molecule. The use of microwaves in spectroscopy essentially became possible due to the development of microwave technology for RADAR during World War II. Rotational spectroscopy is only really practical in the gas phase where the rotational motion is quantized. In solids or liquids the rotational motion is usually quenched due to collisions.

Rotational spectrum from a molecule (to first order) requires that the molecule have a dipole moment, that is a difference between the center of charge and the center of mass, or equivalently a separation between two unlike charges. It is this dipole moment that enables the electric field of the light (microwave) to exert a torque on the molecule causing it to rotate more quickly (in excitation) or slowly (in de-excitation). Diatomic molecules such as dioxygen (O₂), dihydrogen (H₂), etc. do not have a dipole moment and hence no purely rotational spectrum. However, electronic excitations can lead to asymmetric charge distributions and thus provide a net dipole moment to the molecule. Under such circumstances, these molecules will exhibit a rotational spectrum.

Amongst the diatomic molecules, carbon monoxide (CO) has one of the simplest rotational spectra. As for tri-atomic molecules, hydrogen cyanide (HC≡N) has a simple rotational spectrum for a linear molecule and hydrogen isocyanide (HN=C:) for a non-linear molecule. As the number of atoms increases the spectrum becomes more complex as lines due to different transitions start overlapping.

content

1 Understanding the rotational spectrum
- 1.1 Classification of molecules based on rotational behavior
- 1.2 Structure of rotational spectrum
2 Experimental determination of the spectrum
3 Applications
4 References
5 See also
6 External links

Understanding the rotational spectrum

In quantum mechanics the free rotation of a molecule is quantized, that is the rotational energy and the angular momentum can only take certain fixed values; what these values are is simply related to the moment of inertia, $I$ , of the molecule. In general for any molecule, there are three moments of inertia: $I A$ , $I B$ and $I C$ about three mutually orthogonal axes A, B, and C with the origin at the center of mass of the system. A linear molecule is a special case in this regard. These molecules are cylindrically symmetric and one of the moment of inertia ( $I A$ , which is the moment of inertia for a rotation taking place along the axis of the molecule) is negligible (i.e. $I_A \ll I_B = I_C$ ).

Classification of molecules based on rotational behavior

The general convention is to define the axes such that the axis $A$ has the smallest moment of inertia (and hence the highest rotational frequency) and other axes such that $I_A \leq I_B \leq I_C$ . Sometimes the axis $A$ may be associated with the symmetric axis of the molecule, if any. If such is the case, then $I A$ need not be the smallest moment of inertia. To avoid confusion, we will stick with the former convention for the rest of the article. The particular pattern of energy levels (and hence of transitions in the rotational spectrum) for a molecule is determined by its symmetry. A convenient way to look at the molecules is to divide them into four different classes (based on the symmetry of their structure). These are,

Linear molecules (or linear rotors)
Symmetric tops (or symmetric rotors)
Spherical tops (or spherical rotors) and
Asymmetric tops

Dealing with each in turn:

Linear molecules:
- As mentioned earlier, for a linear molecule $I_A \ll I_B = I_C$ . For most of the purposes, $I A$ is taken to be zero. For a linear molecule, the separation of lines in the rotational spectrum can be related directly to the moment of inertia of the molecule, and for a molecule of known atomic masses, can be used to determine the bond lengths (structure) directly. For diatomic molecules this process is trivial, and can be made from a single measurement of the rotational spectrum. For linear molecules with more atoms, rather more work is required, and it is necessary to measure molecules in which more than one isotope of each atom have been substituted (effectively this gives rise to a set of simultaneous equations which can be solved for the bond lengths).
- Examples or linear molecules: dioxygen (O=O), carbon monoxide (O≡C^*), hydroxy radical (OH), carbon dioxide (O=C=O), hydrogen cyanide (HC≡N), carbonyl sulfide (O=C=S), chloroethyne (HC≡CCl), acetylene (HC≡CH)
Symmetric tops:
- A symmetric top is a molecule in which two moments of inertia are the same. As a matter of historical convenience, spectroscopists divide molecules into two classes of symmetric tops, Oblate symmetric tops (saucer or disc shaped) with $I A = I B < I C$ and Prolate symmetric tops (rugby football, or cigar shaped) with $I A < I B = I C$ . The spectra look rather different, and are instantly recognizable. As for linear molecules, the structure of symmetric tops (bond lengths and bond angles) can be deduced from their spectra.
- Examples of symmetric tops:
  - Oblate: benzene (C₆H₆), cyclobutadiene (C₄H₄), ammonia (NH₃)
  - Prolate: chloroform (CHCl₃), propyne (CH₃C≡CH)
Spherical tops:
- A spherical top molecule, can be considered as a special case of symmetric tops with equal moment of inertia about all three axes ( $I A = I B = I C$ ).
- Examples of spherical tops: phosphorus tetramer (P₄), carbon tetrachloride (CCl₄), nitrogen tetrahydride (NH₄), ammonium ion (NH₄⁺), sulfur hexafluoride (SF₆)
Asymmetric tops:
- As you would have guessed a molecule is termed an asymmetric top if all three moments of inertia are different. Most of the larger molecules are asymmetric tops, even when they have a high degree of symmetry. Generally for such molecules a simple interpretation of the spectrum is not normally possible. Sometimes asymmetric tops have spectra that are similar to those of a linear molecule or a symmetric top, in which case the molecular structure must also be similar to that of a linear molecule or a symmetric top. For the most general case, however, all that can be done is to fit the spectra to three different moments of inertia. If the molecular formula is known, then educated guesses can be made of the possible structure, and from this guessed structure, the moments of inertia can be calculated. If the calculated moments of inertia agree well with the measured moments of inertia, then the structure can be said to have been determined. For this approach to determining molecular structure, isotopic substitution is invaluable.
- Examples of asymmetric tops: anthracene (C₁₄H₁₀), water (H₂O), nitrogen dioxide (NO₂)

Structure of rotational spectrum

Linear molecules

An energy level diagram showing some of the transitions involved in the IR vibration-rotation spectrum of a linear molecule: P branch (where

Δ J = - 1

), Q branch (not always allowed,

Δ J = 0

) and R branch (

Δ J = 1

)

These molecules have two degenerate modes of rotation ( $I B = I C$ , $I A = 0$ ). Since we cannot distinguish between the two modes, we need only one rotational quantum number ( $J$ ) to describe the rotational motion of the molecule.

The rotational energy levels ( $F \left( J \right)$ ) of the molecule based on rigid rotor model can be expressed as,

$F\left( J \right) = \tilde B_{e} J \left( J+1 \right) \qquad J = 0,1,2,...$

where $\tilde B_e$ is the rotational constant of the molecule and is related to the moment of inertia of the molecule $I B = I C$ by,

$\tilde B_e = {h \over{8\pi^2cI_B}}$

Selection rules dictate that during emission or absorption the rotational quantum number has to change by unity i.e. $\Delta J = J^{\prime} - J^{\prime\prime} = \pm 1$ . Thus the locations of the lines in a rotational spectrum will be given by,

$\tilde \nu_{J^{\prime}\leftrightarrow J^{\prime\prime}} = F\left( J^{\prime} \right) - F\left( J^{\prime\prime} \right) = 2 \tilde B_e \left( J^{\prime\prime} + 1 \right) \qquad J^{\prime\prime} = 0,1,2,...$

where $J^{\prime\prime}$ denotes the lower energy level and $J^{\prime}$ denotes higher energy level involved in the transition. The height of the lines is determined by the distribution of the molecules in the different levels and the probability of transition between two energy levels.

We observe that, for a rigid rotor, the transition lines are equally spaced in the wavenumber space. However, this is not always the case, except for the rigid rotor model. For non-rigid rotor model, we need to consider changes in the moment of inertia of the molecule. Two primary reasons for this are,

Centrifugal distortion:

When a molecule rotates, the centrifugal force pulls the atoms apart. As a result, the moment of inertia of the molecule increases, thus decreasing $\tilde B_e$ . To account for this a centrifugal distortion correction term is added to the rotational energy levels of the molecule.

$F\left( J \right) = \tilde B_{e} J \left( J+1 \right) - \tilde D_{e} J^2 \left( J+1 \right)^2 \qquad J = 0,1,2,...$

where $\tilde D_e$ is the centrifugal distortion constant.

Accordingly the line spacing for the rotational mode changes to,

$\tilde \nu_{J^{\prime}\leftrightarrow J^{\prime\prime}} = 2 \tilde B_e \left( J^{\prime\prime} + 1 \right) - 4\tilde D_e \left( J^{\prime\prime} +1 \right)^3 \qquad J^{\prime\prime} = 0,1,2,...$

Effect of vibration on rotation:

A molecule is always in vibration. As the molecule vibrates, its moment of inertia changes. Further there is a fictitious force, Coriolis coupling, between the vibrational motion of the nuclei in the rotating (non-inertial) frame. However, as long as the vibrational quantum number does not change (i.e. the molecule is in only one state of vibration), the effect of vibration on rotation are not important, because the time for vibration is much shorter than the time required for rotation. The Coriolis coupling is often negligible, too, if one is interested in low vibrational and rotational quantum numbers only.

Symmetric Top

The rotational motion of a symmetric top molecule can be described by two independent rotational quantum numbers (since two axes have equal moments of inertia, the rotational motion about these axes requires only one rotational quantum number for complete description). Instead of defining the two rotational quantum numbers for two independent axes, we associate one of the quantum number ( $J$ ) with the total angular momentum of the molecule and the other quantum number ( $K$ ) with the angular momentum of the axis which has different moment of inertia (i.e. axis $C$ for oblate symmetric top and axis $A$ for prolate symmetric tops). The rotational energy $F\left(J,K\right)$ of such a molecule, based on rigid rotor assumptions can be expressed in terms of the two previously defined rotational quantum numbers as follows,

$F\left( J,K \right) = \tilde B J \left( J+1 \right) + \left( \tilde A - \tilde B \right) K^2 \qquad J = 0,1,2,... \quad \mbox{and}\quad K = -J, -J+1, ...,-1, 0, 1, ..., J-1, J$

where $\tilde B = {h\over{8\pi^2cI_B}}$ and $\tilde A = {h\over{8\pi^2cI_A}}$ for a prolate symmetric top molecule or $\tilde A = {h\over{8\pi^2cI_C}}$ for an oblate molecule.

Selection rule for the these molecules provide the guidelines for possible transitions. Accordingly,

$\Delta J = \pm 1 \quad \mbox{and} \quad \Delta K = 0$ .

This is so because $K$ is associated with the axis about which the molecule is symmetric and hence has no net dipole moment in that direction. Thus there is no interaction of this mode with the light particles (photon).

This gives the transition wavenumbers of,

$\tilde \nu_{J^{\prime}\leftrightarrow J^{\prime\prime},K} = F\left( J^{\prime},K \right) - F\left( J^{\prime\prime},K \right) = 2 \tilde B \left( J^{\prime\prime} + 1 \right) \qquad J^{\prime\prime} = 0,1,2,...$

which is the same as in the case of a linear molecule.

In case of non-rigid rotors, the first order centrifugal distortion correction is given by,

$F\left( J,K \right) = \tilde B J \left( J+1 \right) + \left( \tilde A - \tilde B \right) K^2 - \tilde D_J J^2\left(J+1\right)^2 - \tilde D_{JK}J\left(J+1\right)K^2 - D_KK^4 \qquad J = 0,1,2,... \quad \mbox{and}\quad K = -J,...,0, ..., J$

The suffixes on the centrifugal distortion constant $D$ indicate the rotational mode involved and are not a function of the rotational quantum number. The location of the transition lines on a spectrum are given by,

Spherical Tops

Unlike other molecules, spherical top molecules have no net dipole moment, and hence they do not exhibit a pure rotational spectrum.

Asymmetric Tops

The spectrum for these molecules usually involves many lines due to three different rotational modes and their combinations. The following analysis is valid for the general case and collapses to the various special cases described above in the appropriate limit.

From the moments of inertia one can define an asymmetry parameter $κ$ as

$\kappa = \frac{2B-A-C}{A-C}$

which varies from -1 for a prolate symmetric top to 1 for an oblate symmetric top.

One can define a scaled rotational Hamiltonian dependent on $J$ and $κ$ . The (symmetric) matrix representation of this Hamiltonian is banded, zero everywhere but the main diagonal and the second subdiagonal. The Hamiltonian can be formulated in six different settings, dependent on the mapping of the principal axes to lab axes and handedness. For the most asymmetric, right-handed representation the diagonal elements are, for $|k|\leq J$

H k, k (κ) = κ k 2

and the second off-diagonal elements (independent of $κ$ ) are

$H_{k,k+2}(\kappa)=\sqrt{[J(J+1)-(k+1)(k+2)][J(J+1)-k(k+1)]}/2$ .

Diagonalising $H$ yields a set of $2 J + 1$ scaled rotational energy levels $E k (κ)$ . The rotational energy levels of the asymmetric rotor for total angular momentum $J$ are then given by

$\frac{A+C}{2}J(J+1)+\frac{A-C}{2}E_k(\kappa)$

Hyperfine interactions:

In addition to the main structure that is observed in microwave spectra due to the rotational motion of the molecules, a whole host of further interactions are responsible for small details in the spectra, and the study of these details provides a very deep understanding of molecular quantum mechanics. The main interactions responsible for small changes in the spectra (additional splittings and shifts of lines) are due to magnetic and electrostatic interactions in the molecule. The particular strength of such interactions differs in different molecules, but in general, the order of these effects (in decreasing significance) is:

electron spin - electron spin interaction (this occurs in molecules with two or more unpaired electrons, and is a magnetic-dipole / magnetic-dipole interaction)
electron spin - molecular rotation (the rotation of a molecule corresponds to a magnetic dipole, which interacts with the magnetic dipole moment of the electron)
electron spin - nuclear spin interaction (the interaction between the magnetic dipole moment of the electron and the magnetic dipole moment of the nuclei (if present)).
electric field gradient - nuclear electric quadrupole interaction (the interaction between the electric field gradient of the electron cloud of the molecule and the electric quadrupole moments of nuclei (if present)).
nuclear spin - nuclear spin interaction (nuclear magnetic moments interacting with one another).

These interactions give rise to the characteristic energy levels that are probed in "magnetic resonance" spectroscopy such as NMR and ESR, where they represent the "zero field splittings" which are always present.

Experimental determination of the spectrum

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Fourier transform infrared (FTIR) spectroscopy can be used to experimentally study rotational spectra. Typically spectra at these wavelengths involve rovibrational excitation, i.e., excitation of both a vibrational and a rotational mode of a molecule.

Traditionally, microwave spectra were determined using a simple arrangement in which low pressure gas was introduced to a section of waveguide between a microwave source (of variable frequency) and a microwave detector. The spectrum was obtained by sweeping the frequency of the source while detecting the intensity of the transmitted radiation. This experimental arrangement has a major difficulty related to the propagation of microwave radiation through waveguides. The physical size of the waveguide restricts the frequency of the radiation that can be transmitted through it. For a given waveguide size (such as X-band) there is a cutoff frequency, and microwave radiation with smaller frequencies (longer wavelengths) cannot be propagated through the waveguide. Additionally, as the frequency is increased, additional modes of propagation become possible, which correspond to different velocities of the radiation propagating down the waveguide (this can be envisaged as the radiation bouncing down the guide, at different angles of reflection). the net result of these considerations is that each size of waveguide is only useful over a rather narrow range of frequencies and must be physically swapped out for a different size of waveguide once this frequency range is exceeded.

More recently, microwave spectra have often been obtained using Fourier Transform Microwave Spectroscopy - a technique invented by

Within the last two years, a further development of Fourier Transform Microwave Spectroscopy has occurred, which may well introduce a new renaissance into microwave spectroscopy. This is the use of "Chirped Pulses" to provide an eletromagnetic wave that has as its Fourier Transform a very wide range of microwave frequencies. (see university of virginia, chemistry department website).

Applications

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Microwave spectroscopy is commonly used in physical chemistry to determine the structure of small molecules (such as ozone, methanol, or water) with high precision. Other common techniques for determining molecular structure, such as X-ray crystallography don't work very well for some of these molecules (especially the gases) and are not as precise. However, microwave spectroscopy is not useful for determining the structures of large molecules such as proteins.

Microwave spectroscopy is one of the principal means by which the constituents of the universe are determined from the earth. It is particularly useful for detecting molecules in the interstellar medium (ISM). One of the early suprises in interstellar chemistry was the existence in the ISM of long chain carbon molecules. It was in attempting to research such molecules in the laboratory that Harry Kroto was led to the laboratory of Rick Smalley and Robert Curl, where it was possible to vaporize carbon under enormous energy conditions. This collaborative experiment led to the discovery of C60, buckminsterfullerene, which led to the award of the 1996 Nobel prize in chemistry to Kroto, Smalley and Curl.