METO 434

METO 434

Homework Set 3

Kinetics and Atmospheric Lifetimes

Due: March 15, 2007

NAME_______________________________________

1. (3) Derive an expression for the steady state concentration of formaldehyde, H₂CO, in terms of CH₄, OH, rate constants, and photolysis rate coefficients. Assume the following reactions control the formaldehyde mixing ratio.

CH₄ + OH -> H₂O + CH₃................. 1

CH₃ + O₂ + M -> CH₃O₂ + M ...........2

CH₃O₂ + NO -> CH₃O + NO₂ ............3

CH₃O + O₂ -> H₂CO + HO₂ ..............4

H₂CO + hn -> H₂ + CO ....................5a

-> HCO + H .........................................5b

2. (3) What is the overall lifetime, in seconds, of hydroperoxy radicals in the polluted troposphere where [O₃] is 100 ppb and [NO] is 20 ppb? Repeat the calculation for the clean troposphere where [O₃] is 30 ppb and [NO] is 0.002 ppb. Use the following reactions and rate constants.

HO₂ + NO -> NO₂ + OH ...... k = 8.1x10^-12 cm³ s^-1

HO₂ + O₃ -> 2O₂ + OH ...... k = 7.3x10^-14 exp(-1275/T) cm³ s^-1

3. (4) You want to determine the rate constant for the reaction between ozone and nitrogen dioxide. To do so, a chamber is filled with 20 ppm O₃ in air and enough NO₂ is added to bring the initial concentration to 1.00 ppm NO₂. The decay of NO₂ is observed as a function of time, pressure, and temperature. The data for five runs are shown on the following table. The uncertainty in the O₃ concentration is 1%; in the initial NO₂ it is 4% with a detection limit of 2 ppb; in the temperature measurement the precision is 0.5 K; the pressure can be read to the nearest 1 mb.

a O₃ + b NO₂ -> Prod.

A) Plot the data in order to prove that the reaction is second order (i.e., a = b = 1). Hint: think about the pressure dependence of a third order reaction. If the reaction proceeds with first order dependence on the molecular number density of O₃ and NO_2,, but otherwise independent of total pressure, it's second order.

B) Express the rate constant (in appropriate units) for 298 K.

C) Estimate the uncertainty in k₂₉₈.

D) Write an expression for the temperature dependence.

E) Estimate the activation energy for this reaction, Ea

F) What is the uncertainty in the Ea?

G) Estimate the lifetime of NO₂in the real atmosphere with respect

to this reaction.

LABORATORY OBSERVATIONS

time (s) NO₂(ppm) P (atm) T(K)

20 0.728 1.00 298

40 0.525 1.00 298

60 0.381 1.00 298

80 0.280 1.00 298

100 0.203 1.00 298

120 0.146 1.00 298

20 0.526 2.00 298

40 0.279 2.00 298

60 0.145 2.00 298

80 0.079 2.00 298

100 0.040 2.00 298

120 0.022 2.00 298

20 0.853 0.50 298

40 0.725 0.50 298

60 0.621 0.50 298

80 0.525 0.50 298

100 0.450 0.50 298

120 0.385 0.50 298

20 0.666 1.00 308

40 0.448 1.00 308

60 0.296 1.00 308

80 0.201 1.00 308

100 0.131 1.00 308

120 0.086 1.00 308

20 0.596 1.00 318

40 0.355 1.00 318

60 0.211 1.00 318

80 0.126 1.00 318

100 0.074 1.00 318

120 0.044 1.00 318

Extra credit (3)

A new, cool-burning gasoline substitute - Sprangbake - is being touted as a means of reducing NO emissions from automobiles. The only problem is that Sprangbake is about 10% (by weight) nitrogen and has a formula approximately C₇H₁₅N_x. Calculate "x" and the concentration of NO expected in the exhaust assuming complete combustion and an AFR of 16; neglect (for the moment) the Zeldovich mechanism. Express your answer in ppm, molec/cm³, and m g/m³. How does the fuel derived [NO] compare to the [NO] expected from the thermal decomposition of air during normal internal combustion?