Absorption Line Physics

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Topics: 1. Absorption line shapes 2. Absorption line strength 3. Line-by-line models Absorption Line Physics Week 4: September 17-21 Reading: Liou 1.3, 4.2.3; Thomas 3.3,4.4,4.5 Absorption Line Shapes Absorption spectrum of a single line is broken into two parts - shape and strength: k ν = Sf(ν ν 0 ) k ν dν = S k ν is absorption coefficient, ν 0 is the line center wavenumber, f(ν ν 0 ) is the line shape function, and S is the line strength. Line shape determined from broadening mechanisms: 1. Natural line width from uncertainty principle is very small. 2. Pressure (collisional) broadening important below stratopause. 3. Doppler broadening important in upper stratosphere and above. Natural Line Width Heisenberg uncertainty principle is E t h/2π ν = E hc = 1 2πt n c t n is time spent in upper state. In thermal IR lifetimes of isolated molecules are t n = 0.1 to 10 sec: ν 10 11 cm 1 (completely negligible) Classically, frequency precision depends on number of cycles in wave: ν ν 1 N = ν 1 νt = 1 t 1

Collisional Broadening Molecular collisions in air greatly reduce upper state lifetimes, and hence broaden absorption lines. Estimate collision time: Mean velocity v = 8k b T/πm 450 m/s Treat molecules as hard spheres of radius r = 2 10 10 m, collides with molecules within 2r of flight line - Volume swept is V = π(2r) 2 v = 2 10 16 m 3 /s Number of molecules per m 3 at STP is n L = 2.69 10 25 m 3 Time between collisions t c = 1/(n L V ) = 1.6 10 10 s Line halfwidth is α 1 2πct c = 0.03 cm 1 Typical halfwidth of 15 µm CO 2 line at 296 K at 1013 mb is 0.07 cm 1. Collisional or pressure broadening causes Lorentz line shape f(ν ν 0 ) = α/π (ν ν 0 ) 2 + α 2 In the microwave the asymmetric Van Vleck-Weisskopf shape is used. Motivate the Lorentz line shape: electric field of emitted wave train E(t) exp( t/t c )e 2πi ν 0t Exponential term from Poisson distribution of collisions. Fourier transform to get to frequency space E( ν) Square to get intensity, so line shape is f( ν ν 0 ) 1 1/t c + 2πi( ν ν 0 ) 1 ( ν ν 0 ) 2 + 1/(2πt c ) 2 2

Pressure Broadening Lorentz line shape: α/π f(ν ν 0 ) = (ν ν 0 ) 2 + α 2 α is Lorentz half-width at half max. Halfwidth is from mean time between collisions (α = 1/2πt c ). Halfwidth is proportional to number of collisions per time α p T (kt/m)1/2 p T 1/2 Pressure broadened absorption line halfwidth ( ) ( p )n T0 α = α 0 p 0 T α 0 is the line width at a reference temperature T 0 and pressure p 0 (n determined empirically). Line halfwidth is proportional to pressure. Lorentz line shape profiles for three pressures. A line width of 0.05 cm 1 at a pressure of 1 bar is typical for vibration-rotation bands. [Goody & Yung, Fig. 3.18] 3

Doppler Broadening Doppler frequency shift from distribution of molecular velocities causes absorption line broadening. Doppler wavenumber shift is ν = ν(1 v/c). Maxwell-Boltzmann distribution of velocities along x is p(v x ) = 1 πv0 e v2 x /v2 0 where v 0 = 2k B T/m and m is mass of molecule. Results in Gaussian line shape for Doppler broadening f D (ν ν 0 ) = 1 exp α D π (ν ν 0) 2 α 2 D α D = ν 2k BT 0 mc 2 Halfwidth at half max is α D ln 2. Note: Doppler width does not depend on molecular properties other than mass. Width is proportional to wavenumber, so importance depends on frequency. a) A comparison of Doppler and Lorentz line shapes. b) Relationship between atmospheric height and linewidth for a microwave line of O 2 and an infrared line of CO 2. [Stephens, Fig. 3.14] 4

Voigt Profile When pressure broadened Lorentz halfwidth becomes comparable to Doppler width, the broadening effects must be convolved to get the Voigt line shape: f V (ν ν 0 ) = a π 3/2 α D + e y2 (x y) 2 + a 2dy where a = α L /α D and x = (ν ν 0 )/α D. There is no simple analytical function for the Voigt profiles, so various approximations are used. In the line wings the Voigt profile has a Lorentz shape. At the line center or core, it has a Doppler behavior. Line profiles: A is Lorentz, B is Doppler, and C is Voigt profile resulting from convolution of A and B. [Lenoble, Fig. 6.1] 5

Absorption Line Strength Line strength is integrated absorption cross section across a line: S = k ν dν Line strength depends on 1) quantum mechanical transition probability, and 2) the fraction of molecules in the lower state. Line strength is temperature dependent through population of states. Boltzmann Distribution of States In Local Thermodynamic Equilibrium the population of states is determined by n i = g i exp( E i /k B T ) n t Q(T ) where n i is the number of molecules in energy level E i, n t is the total number of molecules, k B T is Boltzmann constant times temperature, and g i is the degeneracy of level (number of states with same energy). Q is the partition function: Q(T ) = i g i exp( E i /k B T ) Example: rotational states g J = 2J + 1 E J = hcbj(j + 1) Q r k BT hcb States with energy levels comparable or less than thermal energy k B T are populated, but higher energy states much less populated. 6

The Boltzmann distribution peaks at intermediate J (rotational quantum number). Increasing the temperature moves the peak to higher J. [Kyle, Fig. 8.3] Distribution of rotational energy levels with J for various diatomic molecules at T=250 K. The lower mass molecules have a larger rotational constant B, and hence the higher J states have higher energy and are less populated. [Thomas & Stamnes, Fig. 4.11] 7

Two-level Atom Radiative Processes Transition Process Rate 1. Absorption B 12 n 1 Ī 2. Spontaneous emission 3. Stimulated emission A 21 n 2 B 21 n 2 Ī Stimulated emission: photon with correct energy triggers emission of identical photon from excited molecule. n 1 and n 2 are number of molecules in states 1 and 2. A 21, B 12, and B 21 are Einstein coefficients. Einstein relations: A 21 = (2hν 3 0/c 2 )B 21 g 1 B 12 = g 2 B 21 Non LTE: population of states determined by radiation and collisions. Illustration of the five radiative and collisional processes involved in the rate of population of energy levels in a two-level atom. [Thomas & Stamnes, Fig. 4.7] 8

Line Strength Expressions Simulated emission is like negative absorption. Ratio of stimulated emission to absorption = B 21 n 2 B 12 n 1 = B 21 B 12 g 2 exp( E 2 /k B T ) g 1 exp( E 1 /k B T ) = exp( hcν 0/k B T ) Strength of i th absorption line is S i a i R 2 n L n t [1 exp( hcν 0 /k B T )] n L /n t is fraction of molecules in lower state of transition, R 2 is quantum mechanical transition probability, a i is abundance of this isotope (typically built into strength). Substitute in molecule fraction in lower state to get line strength S i a i R 2 g i exp( hce L,i /k B T ) Q T (T ) [1 exp( hcν 0 /k B T )] E L,i is lower state energy in cm 1, Q T (T ) is Total Internal Partition function (rotational vibrational) Spectroscopic databases have line strength at reference temperature T 0. Temperature dependence of line strength then obtained from S i (T ) = S i (T 0 ) exp( hce L,i/k B T )Q T (T 0 ) [1 exp( hcν 0,i /k B T )] exp( hce L,i /k B T 0 )Q T (T ) [1 exp( hcν 0,i /k B T 0 )] The total partition function Q T (T ) depends on molecule/isotope. 9

HITRAN Spectroscopic Database The 2000 HITRAN Database contains over 1,000,000 spectral lines for 36 different molecules. Information and database is at http://www.hitran.com/. The 1996 HITRAN Database is available on CD-ROM. Relevant quantities in HITRAN database: ν 0 Transition frequency (cm 1 ) S Strength at T 0 = 296 K (cm/molecule) αl,air 0 air broadened halfwidth (cm 1 /atm) at 296 K αl,self 0 self broadened halfwidth (cm 1 /atm) at 296 K E L Lower state energy (cm 1 ) n temperature dependence coefficient for halfwidth The format of the HITRAN 1996 and 2000 database. The HITRAN 2001 format will be the same, except R 2 is replaced by the Einstein A coefficient and the v, v, Q, Q, IER, IREF formats are expanded. 10

The HITRAN numbering scheme for various molecules. 11

Line-by-Line Models Calculate monochromatic optical depth for a layer by summing contribution of all absorption lines, then sum layers vertically, then integrate across spectrum. Optical depth of layer at height z due to lines from a particular gas: τ ν (z) = k ν (z) u(z) = i S i (T )f(ν ν i ; α i ) u(z) Typically, absorption lines within 25 cm 1 of ν are used. The Lorentz halfwidth is obtained from pressure/temperature scaling: ( p p0 ) ( ) n T0 α i = αi 0 T The foreign and self broadening are added with volume mixing ratio q: α 0 i = (1 q)α 0 L,air + qα 0 L,self Add up optical depths from all relevant species, e.g.: τ ν = τ ν,h2 O + τ ν,o3 + τ ν,co2 Integrate optical depth vertically: τ ν = j τ ν (z j ) Integrate monochromatic transmission across spectrum: T ν = ν exp [ τ ν/ cos θ] dν Line-by-line models are accurate but very expensive to run. Line-by-line models use complex algorithms to speed up computation (e.g. FASCODE and LBLRTM): Three functions of different resolutions represent Voigt profile. Line centers added to fine grid; line wings to coarse grid. After all absorption lines added to grids, then spectral grids interpolated finest grid and added. 12

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