Presentation is loading. Please wait.

Presentation is loading. Please wait.

Gas Absorption Line Broadening April 6. Summary in Words of Gas Transitions 3 types of quantized transitions important to us: Electronic (highest energy:

Published byAllyson Chapman Modified over 8 years ago

Similar presentations

Presentation on theme: "Gas Absorption Line Broadening April 6. Summary in Words of Gas Transitions 3 types of quantized transitions important to us: Electronic (highest energy:"— Presentation transcript:

1 Gas Absorption Line Broadening April 6

2 Summary in Words of Gas Transitions 3 types of quantized transitions important to us: Electronic (highest energy: UV-Vis) Vibrational (medium energy: Vis-NIR-Thermal IR) Rotational (Far IR & Microwave) Other types of absorption are not quantized: Photo-Ionization : Ripping electronic off to make ion (Occurs when photon energy > ionization energy of molecule) Photo-Dissociation: Tearing an atom off a molecule (E.g. O 3  O 2 + O* - critical for stratospheric chemistry) (Occurs when photon energy > dissociation energy of molecule) Pure rotational transitions can happen ONLY if molecule has a permanent electric dipole moment: (e.g. H 2 O, CO, O 3 ). Symmetric linear molecules (N 2, CO 2, N 2 O) do not have a permanent dipole moment. From last time…

3 Summary in Words of Gas Transitions (pg 2) Rotational transitions often accompany vibrational transitions Rotational quantum number J changes by (-1,0, or 1) when vibrational quantum number v changes by ± 1. ΔJ = -1  “P-branch” ΔJ = 0  “Q-branch” if it exists! Only allowed if the vibrational transition is “degenerate”, e.g. the ν 2 transition of CO 2 ! ΔJ = +1  “R-branch” The energy associated with ΔJ = ±1 is proportional to the starting J state For example: J = 3  4 takes 3 times more energy than J = 0  1 ! The energy associated with Δv = ±1 does not depend on starting v state: they all take the same energy.

4 Doppler Broadening Molecules travel in velocities according the Maxwell-Boltzmann Distribution. For any velocity component v s, the distribution of v s is given by: where v 0 is the “Root-Mean-Squared” (RMS) velocity along that direction. The frequency shift that is induced by a relative velocity v s is given by: Solving for v s, substituting into p(v s ) and renormalizing leads to: (frequency shift)

5 Summary of Broadening Mechanisms: Doppler Doppler Broadening is due to the doppler effect of moving molecules and leads to a Gaussian shape (weak wings): The Half-Width-at-Half Max (HWHM) of the distribution is: Prop. to transition frequency: bigger for higher-energy transitions. O2 @ 0.76 μm is 6600x larger freq. than O2 @ 60 GHz, so Doppler Broadening will be 6600x larger! Prop to sqrt(T). T=310 K (hot temp) is only 30% larger than T=180 K (cold temp)!

6 Pressure Broadening is due to collisions between molecules as they absorb photons. The Shape is a “Lorentzian”: The HWHM of pressure broadening goes like: Summary of Broadening Mechanisms: Pressure Prop. To Pressure! So can vary many orders of magnitude. Strongest at surface. T-dependence goes like 1/sqrt(T). So again relatively weak. Shape & Width not dependent on transition frequency ν 0.

7 PRESSURE BROADENING

8 Doppler prop to ν 0, so becomes important closer to the earth’s surface for higher energy transitions. Pressure broadening decreases with pressure and hence altitude Z.

9 The Voigt Line Shape When both Doppler & Pressure broadening are comparable, you can’t neglect either one. Then you get the “Voigt” lineshape, which is the convolution of a Lorentz function with a Gaussian distribution.

10 Summary in Words of Gas Transitions 3 types of quantized transitions important to us: Electronic (highest energy: UV-Vis) Vibrational (medium energy: Vis-NIR-Thermal IR) Rotational (Far IR & Microwave) Other types of absorption are not quantized: Photo-Ionization : Ripping electronic off to make ion (Occurs when photon energy > ionization energy of molecule) Photo-Dissociation: Tearing an atom off a molecule (E.g. O 3  O 2 + O* - critical for stratospheric chemistry) (Occurs when photon energy > dissociation energy of molecule) Pure rotational transitions can happen if molcule has permanent electric dipole moment: (e.g. H 2 O, CO, O 3 ). Symmetric linear molecules (N 2, CO 2, N 2 O) do not have permanent dipole moment.

11 Summary in Words of Gas Transitions (pg 2) Rotational transitions accompany vibrational transitions Rotational quantum number J changes by (-1,0, or 1) when vibrational quantum number v changes by ± 1. ΔJ = -1  “P-branch” ΔJ = 0  “Q-branch” if it exists! Only allowed if the vibrational transition is “degenerate”, e.g. the ν 2 transition of CO 2 ! ΔJ = +1  “R-branch” The energy associated with ΔJ = ±1 is proportational to the starting J state, so e.g. J = 3  4 takes 3 times more energy than J = 0  1 The energy associated with Δv = ±1 does not depend on starting v state: they all take the same energy.

Download ppt "Gas Absorption Line Broadening April 6. Summary in Words of Gas Transitions 3 types of quantized transitions important to us: Electronic (highest energy:"

Similar presentations

Pressure and Kinetic Energy

Pressure and Kinetic Energy
1 Microwave Interactions with the Atmosphere S. L. Cruz Pol Electrical and Computer Engineering University of Puerto Rico.

1 Microwave Interactions with the Atmosphere S. L. Cruz Pol Electrical and Computer Engineering University of Puerto Rico.
The Greenhouse Effect. Terrestrial Emissions Terrestrial emissions have energies corresponding to the infrared (IR) region of the electromagnetic spectrum.

The Greenhouse Effect. Terrestrial Emissions Terrestrial emissions have energies corresponding to the infrared (IR) region of the electromagnetic spectrum.
Absorption of EM radiation

Absorption of EM radiation
METO 621 Lesson 6. Absorption by gaseous species Particles in the atmosphere are absorbers of radiation. Absorption is inherently a quantum process. A.

METO 621 Lesson 6. Absorption by gaseous species Particles in the atmosphere are absorbers of radiation. Absorption is inherently a quantum process. A.
Natural Broadening From Heisenberg's uncertainty principle: The electron in an excited state is only there for a short time, so its energy cannot have.

Natural Broadening From Heisenberg's uncertainty principle: The electron in an excited state is only there for a short time, so its energy cannot have.
Vibrational Spectroscopy I

Vibrational Spectroscopy I
METO 621 LESSON 7. Vibrating Rotator If there were no interaction between the rotation and vibration, then the total energy of a quantum state would be.

METO 621 LESSON 7. Vibrating Rotator If there were no interaction between the rotation and vibration, then the total energy of a quantum state would be.
Spectroscopy 1: Rotational and Vibrational Spectra CHAPTER 13.

Spectroscopy 1: Rotational and Vibrational Spectra CHAPTER 13.
Satellites Observations Temperature and albedo. What we need to do How do we get values of temperature and albedo (reflectance) using the instruments.

Satellites Observations Temperature and albedo. What we need to do How do we get values of temperature and albedo (reflectance) using the instruments.
The troposphere is the lowest region in the Earth's (or any planet's) atmosphere. On the Earth, it goes from ground (or water) level up to about 11 miles.

The troposphere is the lowest region in the Earth's (or any planet's) atmosphere. On the Earth, it goes from ground (or water) level up to about 11 miles.
Physics for Scientists and Engineers, 6e Chapter 43 - Molecules and Solids.

Physics for Scientists and Engineers, 6e Chapter 43 - Molecules and Solids.
METO 621 Lesson 5. Natural broadening The line width (full width at half maximum) of the Lorentz profile is the damping parameter, . For an isolated.

METO 621 Lesson 5. Natural broadening The line width (full width at half maximum) of the Lorentz profile is the damping parameter, . For an isolated.
Introduction to Infrared Spectrometry Chap 16. Infrared Spectral Regions Table 16-1 Most used 4000 - 670 2.5 – 15.

Introduction to Infrared Spectrometry Chap 16. Infrared Spectral Regions Table 16-1 Most used – 15.
ECEN 5341/4341 Lecture 9 Chapter 5. Maxwell’s Equations Basic Equations The polarization p couples the fields to the materials The dielectric constant.

ECEN 5341/4341 Lecture 9 Chapter 5. Maxwell’s Equations Basic Equations The polarization p couples the fields to the materials The dielectric constant.
PHOTONS IN CHEMISTRY OUT WHY BOTHER?. E = h ν λν = c [3 10 8 m/s]

PHOTONS IN CHEMISTRY OUT WHY BOTHER?. E = h ν λν = c [ m/s]
Introduction to Infrared Spectroscopy

Introduction to Infrared Spectroscopy
METO 637 LESSON 3. Photochemical Change A quantum of radiative energy is called a photon, and is given the symbol h Hence in a chemical equation we.

METO 637 LESSON 3. Photochemical Change A quantum of radiative energy is called a photon, and is given the symbol h Hence in a chemical equation we.
Spectral Line Broadening Hubeny & Mihalas Chap. 8 Gray Chap. 11

Spectral Line Broadening Hubeny & Mihalas Chap. 8 Gray Chap. 11
(8) Absorption – Visible and IR Physics of the Atmosphere II Atmo II 193a.

(8) Absorption – Visible and IR Physics of the Atmosphere II Atmo II 193a.

Similar presentations

Ads by Google