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Mars: photodesorption from mineral surfaces and its effects on atmospheric stability.
Icarus, 32, 270-298 (with R. Huguenin and M. Maderrazo).

*Carbon monoxide on Jupiter and implications for atmospheric convection. Science, 198,
1031-1034 (with S. Barshay).

*On the radiative damping of atmospheric waves. J. Atmos. Sci., 34, 1386–1401.

1978: *Photochemistry and dynamics of the ozone layer. Annual Rev. Earth Plan. Sci., 6, 143– 174 (with F.N. Alyea and D.M. Cunnold).

Meteorological constraints on tropospheric halocarbon and nitrous oxide destruction by
siliceous land surfaces. Atmos. Environ., 12, 1009-1011 (with F.N. Alyea and D.M.
Cunnold).

A methodology for determining the atmospheric lifetime of fluorocarbons. J. Geophys.
Res., 83, 5493-5500 (with D.M. Cunnold and F.N. Alyea).

*Venus: chemistry of the lower atmosphere prior to the Pioneer Venus Mission. Geophys.
Res. Lett., 5, 973–976.

1979: Wind velocities on Venus: vector determination by radio interferometry. Science, 230, 805-806 (with C. Counselman, S. Gourevitch, R. King, G. Pettengill, I. Shapiro, R. Miller, J. Smith, R. Ramos, and P. Leibrecht).

Venus winds are zonal and retrograde below the clouds. Science, 205, 85-87 (with
C. Counselman, S. Gourevitch, R. King, and G. Loriot).

*On the possible roles of gaseous sulfur and sulfanes in the atmosphere of Venus.
Geophys. Res. Lett., 6, 807–810.

1980: Measurement of CFC13 and CCl4 at Harwell over the period January, 1975November, 1977. Atmos. Environ., 14, 617-621 (with D.M. Cunnold and F.N. Alyea).

Preliminary calculations concerning the maintenance of the zonal mean ozone distribution in the Northern Hemisphere. Pure and Applied Geophys., 118, 329-354 (with D.M. Cunnold and F.N. Alyea).

Kinetic inhibition of CO and N2 reduction in the primitive solar nebula. Astrophys. J., 238, 357-364 (with J. Lewis).

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Atmospheric chemistry of the planet Venus. Chemistry International (IUPAC Bulletin),

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1981: *Nitrogen on Jupiter: a deep atmospheric source. J. Geophys. Res., 86, 9895–9899 (with E. Olaguer).

*Kinetic inhibition of CO and N2 reduction in circumplanetary nebulae: implications for satellite composition. Astrophys. J., 249, 308–317 (with B. Fegley).

1982: *Origin and evolution of planetary atmospheres: an introduction to the problem. Planetary and Space Science, 30, 741-753.

Chemical consequences of major asteroidal impacts on the Earth. In Geological Society of
America Special Paper No. 190, ed. L. Silver and P. Schultz, 215–221 (with J. Lewis,
G. Watkins, and H. Hartman).

*Composition of Jupiter. In Vibrational-Rotational Spectroscopy for Planetary
Atmospheres, eds. J. Mumma, K. Fox, J. Hornstein; NASA Conference Publication 2223,

1983: Composition of Venus atmosphere. In Venus (ed. D. Hunter, L. Colin, T. Donahue, and V. Moroz, Univ. of Arizona Press), 299-430 (with U. von Zahn, S. Kumar, and H. Neimann).

*The Atmospheric Lifetime Experiment, I: introduction, instrumentation and overview,
J. Geophys. Res., 88, 8353-8368 (with P.G. Simmonds, R. Rasmussen, R. Rosen, F.N.
Alyea, C. Cardelino, A. Crawford, D.M. Cunnold, P.J. Fraser, and J. Lovelock).

The Atmospheric Lifetime Experiment, III: lifetime methodology and application to three
years of CFC13 data. J. Geophys. Res., 88, 8379-8400 (with D.M. Cunnold,
R. Rasmussen, P.G. Simmonds, F.N. Alyea, C. Cardelino, A. Crawford, P.J. Fraser, and
R. Rosen).

The Atmospheric Lifetime Experiment, IV: results for CF2C12 based on three years of
data. J. Geophys. Res., 88, 8401-8414 (with D.M. Cunnold, R. Rasmussen, P.G.
Simmonds, F.N. Alyea, C. Cardelino, and A. Crawford).

*The Atmospheric Lifetime Experiment, V: results for CH3CC13 based on three years of
data. J. Geophys. Res., 88, 8415–8426 (with R. Rasmussen, P.G. Simmonds, F.N. Alyea,
D.M. Cunnold, B. Lane, C. Cardelino, and A. Crawford).

The Atmospheric Lifetime Experiment, VI: results for CCl4 based on three years of data.
J. Geophys. Res., 88, 8427-8441 (with P.G. Simmonds, F.N. Alyea, C. Cardelino,
A. Crawford, D.M. Cunnold, B. Lane, J. Lovelock and R. Rasmussen).

1984: *Composition and chemistry of Saturn's atmosphere. In Saturn, ed. T. Gehrels, Univ. of Arizona Press, 88-149 (with H. Larson, J. Caldwell, and D. Gautier).

Planets and their Atmospheres: Origin and Evolution, Academic Press, New York, 470 pgs. (with J. Lewis).

1985: *The photochemistry of the atmosphere of Venus. In The Photochemistry of Atmospheres, ed. J. Levine, Academic Press, New York, 281-336.

*The sulfur cycle and clouds of Venus. In Recent Advances in Planetary Meteorology, ed. G. Hunt, Cambridge University Press, England, 1–17.

*The volcanoes and clouds of Venus, Scientific American, 252, 46–53.

*On the feasibility of quantitative analysis of atmospheric OH by titration. Geophys. Res.
Lett., 12, 597-600.

Predicted chemistry of the deep atmosphere of Uranus prior to the Voyager 2 encounter.
Nature, 318, 48-50 (with B. Fegley).

Equilibrium and non-equilibrium chemistry of Saturn's atmosphere: implications for the
observability of PH3, N2, CO, and GeH4. Astrophys. J., 299, 1067-1078
(with B. Fegley).

1986: A global three-dimensional model of the circulation and chemistry of CFC13, CF2C12, CH3CC13, CCl4, and N2O. J. Geophys. Res., 91, 3985-4001 (with A. Golombek).

Chemical effects of large impacts on the Earth's primitive atmosphere, Nature, 319, 305– 307 (with B. Fegley, H. Hartman, and H. Watkins).

The OCS, H2S, and CS2 fluxes from a salt water marsh. J. Atmos. Chem., 4, 375–396
(with M. Carroll, L. Heidt, and R. Cicerone).

Atmospheric lifetime and annual release estimates for CFC13 and CF2Cl2 for 5 years of
ALE data, J. Geophys. Res., 91, 10797–10817 (with D.M. Cunnold, R. Rasmussen, P.G.
Simmonds, F.N. Alyea, C. Cardelino, A. Crawford, P.J. Fraser and R. Rosen).

Chemical models of the deep atmosphere of Uranus. Astrophys. J., 307, 852-865 (with
B. Fegley).

*Chemistry and chemical evolution of Venus, Saturn, and Titan based on recent spacecraft
data The 25th Vernadsky Memorial Lecture, Akademia Nauk USSR, 35526, 1–27.

1987: *The atmospheres of Venus, Earth, and Mars: a critical comparison. Annual Rev. Earth Planet. Sci., 15, 171-212 (with B. Fegley).

*Bolide impacts, acid rain, and biospheric traumas at the Cretaceous-Tertiary boundary. Earth Planet Sci. Lett., 83, 1-15 (with B. Fegley).

*Atmospheric trends in methyl chloroform and the global average for the hydroxyl radical, Science, 239, 945–950 (with D.M. Cunnold, R. Rasmussen, P.G. Simmonds, F.N. Alyea, A. Crawford, P.J. Fraser and R. Rosen).

1988: *Toward an improved global network for determination of tropospheric ozone climatology and trends. J. Atmos. Chem., 6, 281–298.

*How have the atmospheric concentrations of the halocarbons changed? In The Changing
Atmosphere: Dahlem Konferenzen, eds. S. Rowland and I. Isaksen, J. Wiley & Sons,
Chichester, pp. 33-48.

The predicted abundances of deuterium-bearing gases in the atmospheres of Jupiter and
Saturn. Astrophys. J., 326, 490–508 (with B. Fegley).

Chemical constraints on the water and total oxygen abundance in the deep atmosphere of
Jupiter, Astrophys. J., 324, 621–625 (with B. Fegley).

Carbon tetrachloride lifetime and emissions determined from daily global measurements
during 1978-1985. J. Atmos. Chem., 7, 35–58 (with P.G. Simmonds, D.M. Cunnold, F.N.
Alyea, C. Cardelino, A. Crawford, P.J. Fraser, R. Rasmussen and R. Rosen).

1989: *Solar nebula chemistry: origin of planetary, satellite, and cometary volatiles. In Planetary and Satellite Atmospheres: Origin and Evolution, eds. S. Atreya, J. Pollack, and M. Matthews, Univ. of Arizona Press, 78–136 (with B. Fegley).

Global 3-dimensional model calculations of the budgets and present-day atmospheric lifetimes of CF2CICFC12 (CFC-113) and CHCIF2 (CFC-22), Geophys. Res. Lett., 16, 1153-1156 (with A. Golombek).

Estimation of the rate of volcanism on Venus from reaction rate measurements. Nature, 337,

55-58 (with B. Fegley).

Solar nebula chemistry: implications for volatiles in the solar system. In The Formation and Evolution of Planetary Systems, eds. H. Weaver, F. Paresee, and L. Danly, Cambridge Univ. Press, 171-211 (with B. Fegley).

1990: *On neglect of non-linear momentum terms in solar nebula accretion disc models. Astrophys. J., 348, 725-729.

*Global atmospheric chemistry of CFC-123. Nature, 344, 47-49 (with A. Golombek).
*Atmospheric emissions and trends of nitrous oxide deduced from ten years of
ALE-GAGE data. J. Geophys. Res., 95, 18369-18385 (with D.M. Cunnold, R.
Rasmussen, P.G. Simmonds, F.N. Alyea, A. Crawford, P.J. Fraser, and R. Rosen).
Non-methane hydrocarbon chemistry in the remote marine boundary layer.

1991: Spectroscopy and chemistry of the atmosphere of Uranus. In Uranus, eds. J. Bergstralh, E. Miner, and M.S. Matthews, Univ. of Arizona Press, 147-203 (with B. Fegley, D. Gautier, and T. Owen).

*Global atmospheric chemistry and global pollution. In Energy and the Environment in the 21st Century, ed. J. Tester, MIT Press, Cambridge), 27–39.

*Biomass burning studies and the International Global Atmospheric Chemistry (IGAC) Project. In Global Biomass Burning, ed. J. Levine, MIT Press, Cambridge, 22-28. Comments on "Tropospheric OH in a three-dimensional chemical tracer model: an assessment based on observations of CH3CC13" by C. Spivakovsky et al. J. Geophys. Res., 96, 17391–17393 (with D.M. Cunnold).

A critical comparison between tropical ALE/GAGE methyl chloroform measurements and the three-dimensional model of Spivakovsky and coworkers. J. Geophys. Res., 96, 1738317387 (with D.E. Hartley).

1992: Ozone response to a CO2 doubling: Results from a stratospheric circulation model with heterogeneous chemistry. J. Geophys. Res., 97, 5953–5962 (with G. Pitari, S. Palermi, and G. Visconti).

*Atmosphere, ocean, and land: critical gaps in earth system models. In Report of the 1990 Global Change Institute, ed. D. Ojima, OIES/UCAR, Boulder, pp. 9-38 (with D.E. Hartley).

*Cyclic closure of biogeochemical cycles: Vernadsky Loops. In Report of the 1988 Global Change Institute, ed. B. Moore, OIES/UCAR, Boulder, pp. 79–85.

*Global average concentration and trend for hydroxyl radicals deduced from ALE/GAGE trichloroethane (methyl chloroform) data. J. Geophys. Res., 97, 2445-2461 (with D.M. Cunnold, P.G. Simmonds, F.N. Alyea, R. Boldi, A. Crawford, P.J. Fraser, D. Gutzler, D.E. Hartley, R. Rosen, and R. Rasmussen).

*Earth system science. In The Use of EOS for Studies of Atmospheric Physics, eds. J.
Gille and G. Visconti, Italian Physical Society, North-Holland Elsevier, Amsterdan, pp. 3–
11.

Biogenic and anthropogenic trace gases in the atmosphere. The Use of EOS for Studies of
Atmospheric Physics, eds. J. Gille and G. Visconti, Italian Physical Society, North-
Holland Elsevier, Amsterdam, 45-64 (with G. Brasseur).

*Tropospheric chemistry models. In The Use of EOS for Studies of Atmospheric Physics,
eds. J. Gille and G. Visconti, Italian Physical Society, North-Holland Elsevier, Amsterdam,
pp. 65-76.

1993: In-situ nonmethane hydrocarbon measurements on SAGA3. J. Geophys. Res., 98, 16915– 16932 (with N. Donahue).

A global 3-dimensional model of the stratospheric sulfuric acid layer. J. Atmos. Chem., 16, 179-200 (with A. Golobmek).

*Chemistry and evolution of gaseous circumstellar discs. In Protostars and Protoplanets III, eds. E. Levy and J. Lunine, Univ. of Arizona Press, pp. 1005–1030.

Feasibility of determining surface emissions of trace gases using an inverse method in a three-dimensional chemical transport model. J. Geophys. Res., 98, 5183–5197 (with D.E. Hartley).

*Biogeochemical ocean-atmosphere transfers. Global Biogeochem. Cyc., 7, 245-246

1994: Global trends and annual releases of CC13F and CC12F2 estimated from ALE/GAGE and other measurements from July 1978 to June 1991. J. Geophys. Res., 99, 1107-1126 (with D.M. Cunnold, P.J. Fraser, R.F. Weiss, P.G. Simmonds, B.R. Miller, F.N. Alyea, and A. Crawford).

Examination of tracer transport in the NCAR CCM2 by comparison of CFCl, simulations with ALE/GAGE observations. J. Geophys. Res., 99, 12885–12896 (with D.E. Hartley, D. Williamson, and P. Rasch).

*Global Atmospheric-Biospheric Chemistry, Plenum Press, New York, 261 pgs. (editor). *Global atmospheric-biospheric chemistry. Ambio, 23, 50–61.

*The interactive atmosphere: global atmospheric-biospheric chemistry. In Global Atmospheric-Biospheric Chemistry, ed. R. Prinn, Plenum Press, New York, pp. 1-18. 1995: *Inverse methods in atmospheric chemistry. In Progress and Problems in Atmospheric Chemistry, ed. J. Barker, World Sci. Pub., Singapore, pp. 172–197 (with D.E. Hartley). *Atmospheric trends and lifetime of CH3CCl, and global OH concentrations. Science, 269, 187-192 (with R.F. Weiss B.R. Miller, J. Huang, F.N. Alyea, D.M. Cunnold, P.J. Fraser, D.E. Hartley, and P. G. Simmonds).

Cumulus parameterizations in chemical transport models. J. Geophys. Res., 100, 26173– 26189 (with N. Mahowald and P. Rasch).

*Problems and Uncertainties. In Climate Change and Rice, eds. S. Peng, K. Ingram, H.U. Neue, and L. Ziska, Springer-Verlag, New York, pgs. 3–7, 1995.

1996: Lifetime and emission estimates of 1,1,2-trichlorotrifluoroethane (CFC-113) from daily global background observations June 1982-June 1994. J. Geophys. Res., 101, 12585– 12599 (with P.J. Fraser, D.M. Cunnold, F.N. Alyea, R.F. Weiss, P.G. Simmonds, B.R. Miller, and R. Langenfelds).

Über die Unsicherheit in der politischen Analyse von Klimaänderungen. Spektrum der
Wissenschaft, Dossier 5, pgs. 34-42 (with H.D. Jacoby).

Evaluating chemical transport models: Comparison of different CFC-11 emission
scenarios. J. Geophys. Res., 101, 14381-14385 (with D.E. Hartley, T. Kindler, and D.M.
Cunnold).

Optimizing an inverse method to deduce time varying emissions of trace gases. J.
Geophys. Res., 101, 22823–22831 (with D. Haas-Laursen and D.E. Hartley).

1997: GAGE/AGAGE measurements indicating reductions in global emissions of CC13F and
CCl2F2 in 1992–1994. J. Geophys. Res., 102, 1259–1269 (with D.M. Cunnold, R.F.
Weiss, D.E. Hartley, P.G. Simmonds, P.J. Fraser, B.R. Miller, F.N. Alyea, and L. Porter).
In-situ nonmethane hydrocarbon measurements during the IGAC/MAGE Equatorial
Pacific Experiment, J. Geophys. Res., submitted (with X. Shi).

CO2 emissions limits: economic adjustments and the distribution of burdens, The Energy
Journal, 18, 31–58 (with H.D. Jacoby, R.S. Eckaus, A.D. Ellerman, D.M. Reiner, and
Z.L. Yang).

Deducing CC13F emissions using an inverse method and chemical transport models with
assimilated winds. J. Geophys. Res., in press (with N. Mahowald and P. Rasch).

Transport of "Radon to the remote troposphere using MATCH and assimilated winds from ECMWF and NCEP/NCAR. J. Geophys. Res., in press (with N. Mahowald, P.

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