Presentation is loading. Please wait.

Presentation is loading. Please wait.

Modeling the Distribution of H 2 O and HDO in the upper atmosphere of Venus Mao-Chang Liang Research Center for Environmental Changes, Academia Sinica.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Modeling the Distribution of H 2 O and HDO in the upper atmosphere of Venus Mao-Chang Liang Research Center for Environmental Changes, Academia Sinica."— Presentation transcript:

1 Modeling the Distribution of H 2 O and HDO in the upper atmosphere of Venus Mao-Chang Liang Research Center for Environmental Changes, Academia Sinica C. D. Parkinson (U. of Michigan), S. Bougher (U. of Michigan), A. Brecht (U. of Michigan), S. Rafkin (SwRI Boulder), B. Foster (NCAR HAO), Y. L. Yung (Caltech) 2008 EGU Conference at Vienna, Austria (April 14-18) Mao-Chang Liang Research Center for Environmental Changes, Academia Sinica C. D. Parkinson (U. of Michigan), S. Bougher (U. of Michigan), A. Brecht (U. of Michigan), S. Rafkin (SwRI Boulder), B. Foster (NCAR HAO), Y. L. Yung (Caltech) 2008 EGU Conference at Vienna, Austria (April 14-18)

2 Photochemical modeling 1-D and 2-D Catech/JPL KINETICS Cloud top at 58 km to 112 km 24 species including chlorine, hydrogen, oxygen, and carbon compounds 210 chemical reactions Transport by eddy mixing (1-D) and eddy mixing + advection (2-D) Homopause >> 112 km Advection Downwelling at -0.3 cm s -1 : 75-85 km Upwelling at 0.5 cm s -1 : 85-95 km Downwelling at 0.5 cm s -1 : >95 km 1-D and 2-D Catech/JPL KINETICS Cloud top at 58 km to 112 km 24 species including chlorine, hydrogen, oxygen, and carbon compounds 210 chemical reactions Transport by eddy mixing (1-D) and eddy mixing + advection (2-D) Homopause >> 112 km Advection Downwelling at -0.3 cm s -1 : 75-85 km Upwelling at 0.5 cm s -1 : 85-95 km Downwelling at 0.5 cm s -1 : >95 km

3 Chemical fractionation Water photolysis H 2 O + h  H + OH HDO + h  H + OD or D + OH Hydrogen chloride photolysis HCl + h  H + Cl DCl + h  D + Cl Water photolysis H 2 O + h  H + OH HDO + h  H + OD or D + OH Hydrogen chloride photolysis HCl + h  H + Cl DCl + h  D + Cl

4 Photoabsorption cross sections

5 Dynamical fractionation Hydrogen escape (Gurwell and Yung 1993) H escape: 3.5  10 6 atoms cm -2 s -1 D escape: 3.1  10 4 atoms cm -2 s -1 H production rate HCl photolysis: 8.1  10 10 atoms cm -2 s -1 H 2 O photolysis: 4.8  10 8 atoms cm -2 s -1 Hydrogen escape (Gurwell and Yung 1993) H escape: 3.5  10 6 atoms cm -2 s -1 D escape: 3.1  10 4 atoms cm -2 s -1 H production rate HCl photolysis: 8.1  10 10 atoms cm -2 s -1 H 2 O photolysis: 4.8  10 8 atoms cm -2 s -1

6 1-D model results

7 2-D model results

8 Estimate of downwelling Diabatic heating by air subsidence  T = -w(  T/  z +  T/H)  t  t = t rad ~ 3 day T = 175 K,  T/  z = -4 K/km, H = 4 km  T ~ -18w w ~ 1 cm s -1 Needed to explain the increase of H 2 O above 85 km Diabatic heating by air subsidence  T = -w(  T/  z +  T/H)  t  t = t rad ~ 3 day T = 175 K,  T/  z = -4 K/km, H = 4 km  T ~ -18w w ~ 1 cm s -1 Needed to explain the increase of H 2 O above 85 km

9 UPDATE  Re-vitalized National Center for Atmospheric Research (NCAR) thermospheric general circulation model for Venus (VTGCM);  Lowered the bottom boundary (from ~95km to ~80km) to insure all dynamical influences contributing to the NO and O 2 nightglow layers can be captured;  Applied new Near-IR heating and CO 2 15-micron cooling rates (Roldan et al, 2000);  Analyzed solar cycle variations (F10.7 = 70 to 200)  Used observations from Pioneer Venus Orbiter (PVO) and Venus Express (VEX), including measurements of NO, O 2, and H airglows plus temperatures. Interpreted these global tracers of the thermospheric circulation with the VTGCM;  Goal: To determine the dynamical processes that link the Venus middle and upper atmospheres through general circulation modeling of the upper mesosphere and thermosphere.  Re-vitalized National Center for Atmospheric Research (NCAR) thermospheric general circulation model for Venus (VTGCM);  Lowered the bottom boundary (from ~95km to ~80km) to insure all dynamical influences contributing to the NO and O 2 nightglow layers can be captured;  Applied new Near-IR heating and CO 2 15-micron cooling rates (Roldan et al, 2000);  Analyzed solar cycle variations (F10.7 = 70 to 200)  Used observations from Pioneer Venus Orbiter (PVO) and Venus Express (VEX), including measurements of NO, O 2, and H airglows plus temperatures. Interpreted these global tracers of the thermospheric circulation with the VTGCM;  Goal: To determine the dynamical processes that link the Venus middle and upper atmospheres through general circulation modeling of the upper mesosphere and thermosphere.

10 Venus Thermospheric General Circulation Model (VTGCM): Current Formulation and Structure  Altitude range: ~80-200 km (day); ~80-150 km (night)  Horizontal resolution: 5x5 º latitude-longitude grid (pole-to-pole)  Pressure vertical coordinate (1/2-H intervals): 46-levels  Major Fields: T, U, V, W, O, CO, N 2, CO 2, Z  PCE ions Fields: CO 2 +, O 2 +, N 2 +, NO+, O+, Ne  Minor Fields: O 2 (and O 2 IR nightglow at 1.27  m)  Future Minor Fields: N( 4 S), N( 2 D) (and NO nightglow)  Full 2-hemispheric capability. Timestep = 30.0 secs.  Venus obliquity ~ 177.4 º ( “ seasonal ” cases possible)  Rayleigh friction used to slow SS-AS winds.  Upgraded airglow capability: O 2 -IR, NO-UV(future)  Altitude range: ~80-200 km (day); ~80-150 km (night)  Horizontal resolution: 5x5 º latitude-longitude grid (pole-to-pole)  Pressure vertical coordinate (1/2-H intervals): 46-levels  Major Fields: T, U, V, W, O, CO, N 2, CO 2, Z  PCE ions Fields: CO 2 +, O 2 +, N 2 +, NO+, O+, Ne  Minor Fields: O 2 (and O 2 IR nightglow at 1.27  m)  Future Minor Fields: N( 4 S), N( 2 D) (and NO nightglow)  Full 2-hemispheric capability. Timestep = 30.0 secs.  Venus obliquity ~ 177.4 º ( “ seasonal ” cases possible)  Rayleigh friction used to slow SS-AS winds.  Upgraded airglow capability: O 2 -IR, NO-UV(future)

11 Temperature field

12 Vertical wind

13 Summary If the decrease of H 2 O mixing ratio at ~85 km is caused by photolysis, the isotopic compostion can be explained by photolytic fractionation Inferred downwelling is explained by NO influx in the polar region Inferred upwelling remains undetermined If the decrease of H 2 O mixing ratio at ~85 km is caused by photolysis, the isotopic compostion can be explained by photolytic fractionation Inferred downwelling is explained by NO influx in the polar region Inferred upwelling remains undetermined

Download ppt "Modeling the Distribution of H 2 O and HDO in the upper atmosphere of Venus Mao-Chang Liang Research Center for Environmental Changes, Academia Sinica."

Similar presentations

Zasova L.V., Shakun A.V., Khatuntsev I.V., Ignatiev N.I,(1,2), Brekhovskih U.A.(1), Piccioni G.(3), Drossart P.(4). (1) IKI RAS, Moscow, (2) MIPT, Dolgoprudny,

Zasova L.V., Shakun A.V., Khatuntsev I.V., Ignatiev N.I,(1,2), Brekhovskih U.A.(1), Piccioni G.(3), Drossart P.(4). (1) IKI RAS, Moscow, (2) MIPT, Dolgoprudny,
1 Ionospheres of the Terrestrial Planets Stan Solomon High Altitude Observatory National Center for Atmospheric Research

1 Ionospheres of the Terrestrial Planets Stan Solomon High Altitude Observatory National Center for Atmospheric Research
METO621 Lesson 18. Thermal Emission in the Atmosphere – Treatment of clouds Scattering by cloud particles is usually ignored in the longwave spectrum.

METO621 Lesson 18. Thermal Emission in the Atmosphere – Treatment of clouds Scattering by cloud particles is usually ignored in the longwave spectrum.
METO 621 CHEM Lesson 2. The Stratosphere We will now consider the chemistry of the troposphere and stratosphere. There are two reasons why we can separate.

METO 621 CHEM Lesson 2. The Stratosphere We will now consider the chemistry of the troposphere and stratosphere. There are two reasons why we can separate.
Oxygen: Stratosphere, Mesosphere and Thermosphere Part-3 Chemical Rate Equations Ozone Density vs. Altitude Stratospheric Heating Thermal Conductivity.

Oxygen: Stratosphere, Mesosphere and Thermosphere Part-3 Chemical Rate Equations Ozone Density vs. Altitude Stratospheric Heating Thermal Conductivity.
Modeling the Distribution of H 2 O and HDO in the upper atmosphere of Venus Mao-Chang Liang Research Center for Environmental Changes, Academia Sinica.

Modeling the Distribution of H 2 O and HDO in the upper atmosphere of Venus Mao-Chang Liang Research Center for Environmental Changes, Academia Sinica.
Distribution of H 2 O and SO 2 in the atmosphere of Venus Yung Y. 1, Zhang X. 1, Liang M.-C. 2 and Parkinson C. 3 1 California Institute of Technology.

Distribution of H 2 O and SO 2 in the atmosphere of Venus Yung Y. 1, Zhang X. 1, Liang M.-C. 2 and Parkinson C. 3 1 California Institute of Technology.
CO 2 in the middle troposphere Chang-Yu Ting 1, Mao-Chang Liang 1, Xun Jiang 2, and Yuk L. Yung 3 ¤ Abstract Measurements of CO 2 in the middle troposphere.

CO 2 in the middle troposphere Chang-Yu Ting 1, Mao-Chang Liang 1, Xun Jiang 2, and Yuk L. Yung 3 ¤ Abstract Measurements of CO 2 in the middle troposphere.
Using global models and chemical observations to diagnose eddy diffusion.

Using global models and chemical observations to diagnose eddy diffusion.
Modeling Carbon Species in the Atmosphere of Neptune and Comparison with Spitzer Observations Xi Zhang 1, Mao-Chang Liang 2, Daniel Feldman 1, Julianne.

Modeling Carbon Species in the Atmosphere of Neptune and Comparison with Spitzer Observations Xi Zhang 1, Mao-Chang Liang 2, Daniel Feldman 1, Julianne.
METO 637 Lesson 8. Perturbations of the stratosphere Testing our knowledge of the stratosphere comes from a comparison of the measured and predicted concentrations.

METO 637 Lesson 8. Perturbations of the stratosphere Testing our knowledge of the stratosphere comes from a comparison of the measured and predicted concentrations.
Rafkin et al VTGCM1 VTGCM and Applications to VEX and PVO Data Analysis: Upgraded Simulations (F10.7 ~70 & 200) Venus Express Science Meeting Thuile, Italy.

Rafkin et al VTGCM1 VTGCM and Applications to VEX and PVO Data Analysis: Upgraded Simulations (F10.7 ~70 & 200) Venus Express Science Meeting Thuile, Italy.
METO 637 Lesson 13. Air Pollution The Troposphere In the Stratosphere we had high energy photons so that oxygen atoms and ozone dominated the chemistry.

METO 637 Lesson 13. Air Pollution The Troposphere In the Stratosphere we had high energy photons so that oxygen atoms and ozone dominated the chemistry.
METO 637 Lesson 20. Planetary Atmospheres The existence of an atmosphere depends on three factors: (1) How close the planet is to the sun – basically.

METO 637 Lesson 20. Planetary Atmospheres The existence of an atmosphere depends on three factors: (1) How close the planet is to the sun – basically.
CHAPMAN MECHANISM FOR STRATOSPHERIC OZONE (1930) O O 3 O2O2 slow fast Odd oxygen family [O x ] = [O 3 ] + [O] R2 R3 R4 R1.

CHAPMAN MECHANISM FOR STRATOSPHERIC OZONE (1930) O O 3 O2O2 slow fast Odd oxygen family [O x ] = [O 3 ] + [O] R2 R3 R4 R1.
* Reading Assignments:

* Reading Assignments:
Warm Up 3/4/08 True or False: The seasons are caused by changes in Earth’s distance from the sun. False Does land or water heat more rapidly? Land heats.

Warm Up 3/4/08 True or False: The seasons are caused by changes in Earth’s distance from the sun. False Does land or water heat more rapidly? Land heats.
Photochemical Distribution of Venusian Sulphur and Halogen Species AND Why Vulcanism cannot be the source for Venusian SO 2 above 80km C. D. Parkinson.

Photochemical Distribution of Venusian Sulphur and Halogen Species AND Why Vulcanism cannot be the source for Venusian SO 2 above 80km C. D. Parkinson.
Introduction to Atmospheric Chemistry Measurements-I John Ortega National Center for Atmospheric Research Boulder, CO, USA National Center for Atmospheric.

Introduction to Atmospheric Chemistry Measurements-I John Ortega National Center for Atmospheric Research Boulder, CO, USA National Center for Atmospheric.
New Insights into the Atmospheric Chemistry of Venus from Venus Express Yuk L. Yung Caltech GISS Seminar, Mar 24 2012.

New Insights into the Atmospheric Chemistry of Venus from Venus Express Yuk L. Yung Caltech GISS Seminar, Mar

Similar presentations

Ads by Google