Glossary

6.2 Rotational motion of diatomic and polyatomic molecules

4 min readjuly 30, 2024

Rotational motion in molecules is a key aspect of molecular physics, revealing insights into molecular structure and behavior. Diatomic molecules have simpler rotational motion due to a single rotational axis, while polyatomic molecules exhibit more complex rotational dynamics with multiple axes.

Understanding rotational motion helps explain molecular spectra and energy levels. The approximates diatomic rotation, while symmetry and moments of inertia play crucial roles in polyatomic molecules. This knowledge connects to broader concepts of molecular vibration and rotation.

Rotational Motion of Molecules

Rotational Axes and Energy Levels

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  • Diatomic molecules have only one rotational axis perpendicular to the bond axis, while polyatomic molecules can have multiple rotational axes depending on their geometry and symmetry (linear, symmetric top, asymmetric top)
  • The and spectra of diatomic molecules are simpler compared to polyatomic molecules due to the presence of a single
  • Polyatomic molecules exhibit more complex rotational motion, with different moments of inertia around each principal axis, leading to a greater number of rotational energy levels and more intricate spectra

Selection Rules and Transitions

  • The selection rules for rotational transitions differ between diatomic and polyatomic molecules, with polyatomic molecules having additional allowed transitions based on their symmetry
    • Molecules with a permanent electric dipole moment (polar molecules) have allowed rotational transitions with ΔJ = ±1, while molecules without a permanent dipole moment (non-polar molecules) have forbidden rotational transitions
    • The parity of the rotational wavefunctions also affects the allowed transitions, with even-to-even and odd-to-odd transitions being allowed for symmetric molecules, while asymmetric molecules have more relaxed selection rules

Rotational Energy Levels for Diatomic Molecules

Rigid Rotor Approximation and Hamiltonian

  • The rotational energy levels of a diatomic molecule can be derived using the rigid rotor approximation, which assumes the bond length is fixed and the molecule rotates as a single entity
  • The rotational Hamiltonian for a diatomic molecule is given by H=J2/(2I)H = J^2 / (2I), where JJ is the operator and II is the moment of inertia

Quantized Energy Levels and Wavefunctions

  • The rotational energy levels are quantized and given by EJ=J(J+1)2/(2I)E_J = J(J+1)ℏ^2 / (2I), where JJ is the rotational quantum number (J=0,1,2,...J = 0, 1, 2, ...) and is the reduced
    • Example: For the CO molecule, with I=1.46×1046I = 1.46 \times 10^{-46} kg m², the first few rotational energy levels are E0=0E_0 = 0, E1=7.63×1023E_1 = 7.63 \times 10^{-23} J, E2=3.05×1022E_2 = 3.05 \times 10^{-22} J
  • The rotational wavefunctions for a diatomic molecule are the spherical harmonics, YJM(θ,φ)Y_J^M(θ,φ), where JJ is the rotational quantum number and MM is the magnetic quantum number (M=J,J+1,...,J1,JM = -J, -J+1, ..., J-1, J)
    • The rotational wavefunctions describe the angular distribution of the molecule and satisfy the Schrödinger equation for the rotational motion

Symmetry Effects on Rotational Motion

Degenerate Energy Levels and Symmetry

  • Molecular symmetry plays a crucial role in determining the allowed rotational energy levels and transitions of a molecule
  • Molecules with higher symmetry, such as linear and symmetric top molecules, have degenerate rotational energy levels due to the presence of multiple equivalent rotational axes
    • Example: The rotational energy levels of a linear molecule (CO₂) are doubly degenerate, while those of a spherical top molecule (CH₄) are (2J+1)-fold degenerate
  • Asymmetric top molecules have distinct moments of inertia around each principal axis, leading to non-degenerate rotational energy levels and more complex spectra

Electric Dipole Moment and Parity

  • The selection rules for rotational transitions are governed by the symmetry of the molecule and the electric dipole moment
  • Molecules with a permanent electric dipole moment (polar molecules like HCl) have allowed rotational transitions with ΔJ = ±1, while molecules without a permanent dipole moment (non-polar molecules like O₂) have forbidden rotational transitions
  • The parity of the rotational wavefunctions also affects the allowed transitions, with even-to-even and odd-to-odd transitions being allowed for symmetric molecules, while asymmetric molecules have more relaxed selection rules

Moments of Inertia for Different Geometries

Diatomic and Linear Molecules

  • The moment of inertia is a measure of a molecule's resistance to rotational motion and depends on the mass distribution and geometry of the molecule
  • For a diatomic molecule, the moment of inertia is given by I=μr2I = μr^2, where μμ is the reduced mass and rr is the bond length
    • Example: For the HCl molecule, with mH=1.67×1027m_H = 1.67 \times 10^{-27} kg, mCl=5.89×1026m_{Cl} = 5.89 \times 10^{-26} kg, and r=1.27×1010r = 1.27 \times 10^{-10} m, the moment of inertia is I=2.65×1047I = 2.65 \times 10^{-47} kg m²
  • Linear polyatomic molecules have two equal moments of inertia perpendicular to the molecular axis (Ix=IyI_x = I_y) and a zero moment of inertia along the molecular axis (Iz=0I_z = 0)

Symmetric and Asymmetric Top Molecules

  • Symmetric top molecules, such as ammonia (NH₃) and methane (CH₄), have two equal moments of inertia (Ix=IyI_x = I_y) and a distinct moment of inertia along the symmetry axis (IzI_z)
  • Asymmetric top molecules, such as water (H₂O) and hydrogen peroxide (H₂O₂), have three distinct moments of inertia (IxIyIzI_x ≠ I_y ≠ I_z)
  • The moments of inertia can be calculated using the parallel axis theorem, I=Σ(miri2)I = Σ(m_i r_i^2), where mim_i is the mass of each atom and rir_i is the distance of each atom from the rotational axis
    • Example: For the H₂O molecule, with rOH=0.958r_{OH} = 0.958 Å and HOH=104.5°∠HOH = 104.5°, the moments of inertia are Ix=1.02×1047I_x = 1.02 \times 10^{-47} kg m², Iy=1.92×1047I_y = 1.92 \times 10^{-47} kg m², and Iz=2.94×1047I_z = 2.94 \times 10^{-47} kg m²

Key Terms to Review (18)

Angular momentum: Angular momentum is a physical quantity that represents the rotational motion of an object, defined as the product of its moment of inertia and its angular velocity. In molecular physics, angular momentum plays a crucial role in understanding how diatomic and polyatomic molecules rotate and how these rotations influence their energy levels and spectra. The conservation of angular momentum is also a key principle in molecular dynamics, dictating the behavior of molecules during collisions and interactions.
Boltzmann Constant: The Boltzmann constant is a fundamental physical constant that relates the average kinetic energy of particles in a gas with the temperature of the gas. It bridges the macroscopic and microscopic worlds, enabling calculations in statistical mechanics and thermodynamics. Its significance extends to understanding molecular behavior, energy distributions, and the interactions of molecules in various states.
Classical Mechanics: Classical mechanics is a branch of physics that deals with the motion of objects and the forces acting upon them, based on principles established by Newton. It provides a framework for understanding physical systems at the macroscopic scale and plays a critical role in modeling molecular behavior, interactions, and movements.
Infrared spectroscopy: Infrared spectroscopy is an analytical technique that utilizes the infrared region of the electromagnetic spectrum to identify and study chemical substances based on their molecular vibrations. This method is particularly useful for determining functional groups in organic compounds and understanding molecular structure, as it relates to energy levels associated with vibrational and rotational transitions within molecules.
J-transition: A j-transition refers to the rotational transitions that occur in diatomic and polyatomic molecules when they absorb or emit radiation, resulting in changes to their angular momentum. These transitions are characterized by a change in the rotational quantum number, 'j', which signifies the energy levels associated with the rotation of molecules. Understanding j-transitions is crucial for analyzing molecular spectra and how molecules interact with electromagnetic radiation.
Magnetic quantum number m: The magnetic quantum number m is a quantum number that describes the orientation of an atomic orbital in space, indicating the specific angular momentum associated with that orbital. It is an essential part of quantum mechanics and plays a crucial role in determining the energy levels and shapes of diatomic and polyatomic molecules during rotational motion, affecting how these molecules interact with external magnetic fields.
Microwave spectroscopy: Microwave spectroscopy is a technique used to study the rotational transitions of molecules by measuring the absorption of microwave radiation. This method provides insights into the rotational energy levels of molecules, which is crucial for understanding their physical and chemical properties, particularly in gases. The technique connects closely with the analysis of molecular structures and dynamics.
Moment of Inertia: The moment of inertia is a physical quantity that measures an object's resistance to rotational motion about an axis. It depends not only on the mass of the object but also on the distribution of that mass relative to the axis of rotation. This concept is crucial for understanding how molecules rotate and interact with electromagnetic radiation, particularly in spectroscopy.
Non-rigid rotor: A non-rigid rotor refers to a molecular model where the distances between atoms can change during rotational motion, unlike a rigid rotor where distances remain fixed. This concept is particularly relevant when studying diatomic and polyatomic molecules, as it allows for the inclusion of vibrational modes that can affect rotational energy levels and spectra. Understanding the non-rigid rotor model is crucial for accurately describing the behavior of molecules in real-world scenarios where flexibility and vibrational interactions play significant roles.
Planck's Constant: Planck's constant is a fundamental physical constant that describes the quantization of energy in quantum mechanics. It relates the energy of a photon to the frequency of its associated electromagnetic wave, establishing a crucial link between wave and particle behavior in molecular physics and spectroscopy.
Quantized rotational levels: Quantized rotational levels refer to the discrete energy states that diatomic and polyatomic molecules can occupy due to their rotational motion. This concept arises from the principles of quantum mechanics, which dictate that certain physical properties, like angular momentum, can only take on specific values. As molecules rotate, they can only achieve certain energy levels, defined by their moment of inertia and the quantum number associated with their rotational state.
Quantum Mechanics: Quantum mechanics is a fundamental theory in physics that describes the behavior of matter and energy at the smallest scales, such as atoms and subatomic particles. It introduces concepts like wave-particle duality and the uncertainty principle, providing a mathematical framework for understanding phenomena like electronic transitions, molecular rotation, and statistical distributions.
Rigid Rotor Model: The rigid rotor model is a simplified representation of a rotating molecule, where the bond length and angles between atoms are considered fixed, allowing for easier calculations of rotational energy levels and spectra. This model serves as a foundation for understanding molecular rotation and connects to concepts such as microwave spectroscopy, vibrational transitions, and the dynamics of diatomic and polyatomic molecules.
Rotational energy levels: Rotational energy levels refer to the discrete energy states associated with the rotation of molecules, particularly diatomic and polyatomic molecules. These energy levels arise from the quantization of angular momentum, which dictates that molecules can only occupy specific rotational states. The transitions between these levels can be observed through interactions with electromagnetic radiation, linking them to the overall molecular energy landscape and how molecules absorb or emit light.
Rotational quantum number j: The rotational quantum number j is a quantum number that represents the total angular momentum of a molecule in its rotational states. It plays a crucial role in determining the energy levels associated with the rotation of diatomic and polyatomic molecules, influencing their spectral lines and behavior under different conditions.
Rotational spectra: Rotational spectra refer to the spectrum of electromagnetic radiation emitted or absorbed by molecules as they undergo rotational transitions. These transitions occur when molecules rotate about their axes and are closely related to the moments of inertia and the energy levels of the rotational states, particularly in diatomic and polyatomic molecules. Understanding rotational spectra is crucial for interpreting molecular behavior, energy states, and interactions in the context of molecular physics.
Rotational-vibrational coupling: Rotational-vibrational coupling refers to the interaction between the rotational and vibrational motions of molecules, particularly diatomic and polyatomic ones. This coupling occurs when the energy levels of rotational motion are influenced by vibrational modes, leading to a complex interplay that affects molecular spectra and dynamics. Understanding this coupling is crucial for interpreting how molecules absorb and emit energy in different rotational and vibrational states.
Symmetry properties: Symmetry properties refer to the characteristics of a system that remain unchanged under certain transformations, such as rotation or reflection. In molecular physics, particularly concerning rotational motion, these properties play a crucial role in determining the behavior of diatomic and polyatomic molecules, influencing their energy levels and rotational spectra.
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