Your search keyword '"Daniel J. McCleese"' showing total 31 results

1. Asymmetries in Snowfall, Emissivity, and Albedo of Mars' Seasonal Polar Caps: Mars Climate Sounder Observations

Author

James H. Shirley, T. Horvath, John T. Schofield, C. E. Gary-Bicas, Armin Kleinböhl, Nicholas G. Heavens, Paul O. Hayne, David M. Kass, Sylvain Piqueux, and Daniel J. McCleese

Subjects

Geophysics, Space and Planetary Science, Geochemistry and Petrology, Infrared, Earth and Planetary Sciences (miscellaneous), Emissivity, Environmental science, Polar, Mars Exploration Program, Albedo, Snow, Atmospheric sciences

Published

2020

2. Rapid Expansion and Evolution of a Regional Dust Storm in the Acidalia Corridor During the Initial Growth Phase of the Martian Global Dust Storm of 2018

Author

Sylvain Piqueux, James H. Shirley, David M. Kass, Armin Kleinböhl, Nicholas G. Heavens, John T. Schofield, L. J. Steele, Daniel J. McCleese, and S. Suzuki

Subjects

Martian, Geophysics, Dust storm, Rapid expansion, Growth phase, General Earth and Planetary Sciences, Environmental science, Atmosphere of Mars, Mars Exploration Program, Atmospheric sciences

Published

2020

3. Impact of gravity waves on the middle atmosphere of Mars: a non-orographic gravity wave parameterization based on Global Climate modeling and MCS observations

Author

John T. Schofield, David M. Kass, Thomas Navarro, Armin Kleinböhl, Daniel J. McCleese, Gabriella Gilli, Aymeric Spiga, François Forget, Ehouarn Millour, Luca Montabone, Observatório Astronómico de Lisboa, Laboratoire de Météorologie Dynamique (UMR 8539) (LMD), Institut national des sciences de l'Univers (INSU - CNRS)-École polytechnique (X)-École des Ponts ParisTech (ENPC)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Département des Géosciences - ENS Paris, École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), Earth, Planetary and Space Sciences, University of California, Los Angeles, CA, USA, Space Science Institute [Boulder] (SSI), Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), and California Institute of Technology (CALTECH)

Subjects

Martian, Earth and Planetary Astrophysics (astro-ph.EP), 010504 meteorology & atmospheric sciences, Atmospheric circulation, Northern Hemisphere, FOS: Physical sciences, Mars Exploration Program, Atmosphere of Mars, [SDU.STU.ME]Sciences of the Universe [physics]/Earth Sciences/Meteorology, Atmospheric sciences, 01 natural sciences, Mesosphere, Physics - Atmospheric and Oceanic Physics, Geophysics, 13. Climate action, Space and Planetary Science, Geochemistry and Petrology, Meridional flow, Atmospheric and Oceanic Physics (physics.ao-ph), Earth and Planetary Sciences (miscellaneous), Gravity wave, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph], Geology, 0105 earth and related environmental sciences, Astrophysics - Earth and Planetary Astrophysics

Abstract

The impact of gravity waves (GW) on diurnal tides and the global circulation in the middle/upper atmosphere of Mars is investigated using a General Circulation Model (GCM). We have implemented a stochastic parameterization of non-orographic GW into the Laboratoire de M\'et\'eorologie Dynamique (LMD) Mars GCM (LMD-MGCM) following an innovative approach. The source is assumed to be located above typical convective cells ($\sim$ 250 Pa) and the effect of GW on the circulation and predicted thermal structure above 1 Pa ($\sim$ 50 km) is analyzed. We focus on the comparison between model simulations and observations by the Mars Climate Sounder (MCS) on board Mars Reconnaissance Orbiter during Martian Year 29. MCS data provide the only systematic measurements of the Martian mesosphere up to 80 km to date. The primary effect of GW is to damp the thermal tides by reducing the diurnal oscillation of the meridional and zonal winds. The GW drag reaches magnitudes of the order of 1 m/s/sol above 10$^{-2}$ Pa in the northern hemisphere winter solstice and produces major changes in the zonal wind field (from tens to hundreds of m/s), while the impact on the temperature field is relatively moderate (10-20K). It suggests that GW induced alteration of the meridional flow is the main responsible for the simulated temperature variation. The results also show that with the GW scheme included, the maximum day-night temperature difference due to the diurnal tide is around 10K, and the peak of the tide is shifted toward lower altitudes, in better agreement with MCS observations., Comment: JGR (Planets), accepted

Published

2020

4. Hydrogen escape from Mars enhanced by deep convection in dust storms

Author

James H. Shirley, Nicholas G. Heavens, Armin Kleinböhl, Michael Chaffin, Sylvain Piqueux, Paul O. Hayne, Jasper Halekas, John T. Schofield, Daniel J. McCleese, and David M. Kass

Subjects

Martian, Water transport, 010504 meteorology & atmospheric sciences, Astronomy and Astrophysics, Storm, Atmosphere of Mars, Mars Exploration Program, Atmospheric sciences, 01 natural sciences, Atmosphere, Atmospheric chemistry, 0103 physical sciences, Environmental science, 010303 astronomy & astrophysics, Water vapor, 0105 earth and related environmental sciences

Abstract

Present-day water loss from Mars provides insight into Mars’s past habitability1–3. Its main mechanism is thought to be Jeans escape of a steady hydrogen reservoir sourced from odd-oxygen reactions with near-surface water vapour2, 4,5. The observed escape rate, however, is strongly variable and correlates poorly with solar extreme-ultraviolet radiation flux6–8, which was predicted to modulate escape 9 . This variability has recently been attributed to hydrogen sourced from photolysed middle atmospheric water vapour 10 , whose vertical and seasonal distribution is only partly characterized and understood11–13. Here, we report multi-annual observational estimates of water content and dust and water transport to the middle atmosphere from Mars Climate Sounder data. We provide strong evidence that the transport of water vapour and ice to the middle atmosphere by deep convection in Martian dust storms can enhance hydrogen escape. Planet-encircling dust storms can raise the effective hygropause (where water content rapidly decreases to effectively zero) from 50 to 80 km above the areoid (the reference equipotential surface). Smaller dust storms contribute to an annual mode in water content at 40−50 km that may explain seasonal variability in escape. Our results imply that Martian atmospheric chemistry and evolution can be strongly affected by the meteorology of the lower and middle atmosphere of Mars. Mars Climate Sounder’s multi-annual observations of the vertical distribution of water and dust in the Martian atmosphere show that deep convection from dust storms transports water from the lower to the middle atmosphere, enhancing water loss to space.

Published

2018

5. Discovery of a widespread low-latitude diurnal CO2 frost cycle on Mars

Author

John T. Schofield, Armin Kleinböhl, David M. Kass, Paul O. Hayne, James H. Shirley, Daniel J. McCleese, Nicholas G. Heavens, and Sylvain Piqueux

Subjects

Martian, 010504 meteorology & atmospheric sciences, Water on Mars, Ice crystals, Martian soil, Mars Exploration Program, Atmosphere of Mars, Atmospheric sciences, 01 natural sciences, Astrobiology, Geophysics, Olympus Mons, Space and Planetary Science, Geochemistry and Petrology, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Martian polar ice caps, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

While the detection of CO2 ice has only been reported outside the Martian polar regions at very high elevation (i.e., Elysium, Olympus Mons, and the Tharsis Montes), nighttime surface observations by the Mars Climate Sounder on board the Mars Reconnaissance Orbiter document the widespread occurrence of atmospherically corrected ground temperatures consistent with the presence of extensive carbon dioxide frost deposits in the dusty low thermal inertia units at middle/low latitudes. Thermal infrared emissivities, interpreted in conjunction with mass balance modeling, suggest micrometer size CO2 ice crystals forming optically thin layers never exceeding a few hundreds of microns in thickness (i.e., 10−2 kg m−2) locally, which is insufficient to generate a measurable diurnal pressure cycle (<

Published

2016

6. Interannual similarity in the Martian atmosphere during the dust storm season

Author

Daniel J. McCleese, Armin Kleinböhl, John T. Schofield, M. D. Smith, and David M. Kass

Subjects

Daytime, 010504 meteorology & atmospheric sciences, Storm, Mars Exploration Program, Atmosphere of Mars, Atmospheric sciences, 01 natural sciences, Geophysics, Planet, Dust storm, Climatology, 0103 physical sciences, General Earth and Planetary Sciences, Environmental science, Solstice, 010303 astronomy & astrophysics, Southern Hemisphere, 0105 earth and related environmental sciences

Abstract

We find that during the dusty season on Mars (southern spring and summer) of years without a global dust storm there are three large regional-scale dust storms. The storms are labeled A, B, and C in seasonal order. This classification is based on examining the zonal mean 50 Pa (approximately 25 km) daytime temperature retrievals from TES/MGS and MCS/MRO over 6 Mars Years. Regional-scale storms are defined as events where the temperature exceeds 200 K. Examining the MCS dust field at 50 Pa indicates that warming in the Southern Hemisphere is dominated by direct heating, while northern high latitude warming is a dynamical response. A storms are springtime planet encircling Southern Hemisphere events. B storms are southern polar events that begin near perihelion and last through the solstice. C storms are southern summertime events starting well after the end of the B storm. C storms show the most interannual variability.

Published

2016

7. No widespread dust in the middle atmosphere of Mars from Mars Climate Sounder observations

Author

Daniel J. McCleese, John T. Schofield, Armin Kleinböhl, David M. Kass, and W. A. Abdou

Subjects

Atmosphere, Daytime, Altitude, Water on Mars, Space and Planetary Science, Extinction (astronomy), Environmental science, Astronomy and Astrophysics, Storm, Atmosphere of Mars, Mars Exploration Program, Atmospheric sciences

Abstract

It has been established that dust in the atmosphere of Mars is not distributed homogeneously in the vertical but exhibits layering in the lower atmosphere. Recently published results also suggest a dust maximum in the middle atmosphere that predominantly occurs at 50–60 km altitude on the daytime hemisphere. We use measurements from the Mars Climate Sounder to investigate the distribution of dust above ∼ 40 km altitude. Our results do not support the existence of widespread dust in the middle atmosphere of Mars inferred from earlier observations. The average dust extinction does not exceed 10 - 6 km−1 at 463 cm−1 above 50 km altitude in atmospheric conditions without large dust storms.

Published

2015

8. Extreme detached dust layers near Martian volcanoes: Evidence for dust transport by mesoscale circulations forced by high topography

Author

David M. Kass, John T. Schofield, Sylvain Piqueux, Daniel J. McCleese, Armin Kleinböhl, Paul O. Hayne, James H. Shirley, Nicholas G. Heavens, and Bruce A. Cantor

Subjects

Martian, Atmosphere, Geophysics, Olympus Mons, Dust storm, Tharsis Montes, Mesoscale meteorology, General Earth and Planetary Sciences, Storm, Mars Exploration Program, Atmospheric sciences, Geology

Abstract

Modeling suggests that thermal circulations over Mars's highest volcanoes transport water vapor and dust from the surface into the middle atmosphere, forming detached layers in these constituents. Intense vertical mixing also takes place in regional and global dust storms, which can generate detached layers that are extreme in both altitude and magnitude. Here we employ observations by the Mars Climate Sounder (MCS) on board Mars Reconnaissance Orbiter, taking advantage of improved vertical coverage in MCS's aerosol retrievals, to discover a new class of extreme detached dust layers (EDDLs). Observed during minimal dust storm activity and furthermore distinguished by their potentially large and measurable horizontal extent (>1000 km), these EDDLs cluster near Olympus Mons and the Tharsis Montes, from which they likely originate. The existence of these EDDLs suggests that vertical mixing by topographic circulations can be much stronger than previously modeled and more frequent than previously observed.

Published

2015

9. Temperatures and aerosol opacities of the Mars atmosphere at aphelion: Validation and inter-comparison of limb sounding profiles from MRO/MCS and MGS/TES

Author

Daniel J. McCleese, Jennifer Benson, John T. Schofield, Joshua L. Bandfield, J. H. Shirley, Timothy H. McConnochie, D. M. Kass, Nicholas G. Heavens, David P. Hinson, and A. Kleinböhl

Subjects

Thermal Emission Spectrometer, Astronomy and Astrophysics, Atmosphere of Mars, Mars Exploration Program, Atmospheric sciences, Aerosol, law.invention, Atmosphere, Orbiter, Depth sounding, Space and Planetary Science, law, Environmental science, Radio occultation

Abstract

We exploit the relative stability and repeatability of the Mars atmosphere at aphelion for an inter-comparison of Mars Global Surveyor/Thermal Emission Spectrometer (MGS/TES) and Mars Reconnaissance Orbiter/Mars Climate Sounder (MRO/MCS) nighttime temperature profiles and aerosol opacity profiles in Mars years 25, 26, 29, 30, and 31. Cross-calibration of these datasets is important, as they together provide an extended climatology for this planetary atmosphere. As a standard of comparison we employ temperature profiles obtained by radio occultation methods during the MGS mission in Mars years 24, 25, and 26. We first compare both zonal mean TES limb sounding profiles and zonal mean MCS limb sounding profiles with zonal means of radio occultation temperature profiles for the same season (Ls = 70–80°) and latitudes (55–70°N). We employ a statistical z test for quantifying the degree of agreement of temperature profiles by pressure level. For pressures less than 610 Pa (altitudes > 3 km), the ensemble mean temperature difference between the radio occultation and TES limb sounding profiles found in these comparisons was 1.7 ± 0.7 K. The ensemble mean temperature difference between radio occultation and MCS profiles was 1.4 ± 1.0 K. These differences fall within the formal error estimates for both TES and MCS, validating the accuracy of the instruments and their respective retrieval algorithms. In the second phase of our investigation, we compare aphelion season zonal mean TES limb sounding temperature, water ice opacity, and dust opacity profiles with those obtained at the same latitudes in different years by MCS. The ensemble mean temperature difference found for three comparisons between TES and MCS zonal mean temperature profiles was 2.8 ± 2.1 K. MCS and TES temperatures between 610 Pa and 5 Pa from 55 to 70°N are largely in agreement (with differences

Published

2015

10. Variability of the martian seasonal CO2 cap extent over eight Mars Years

Author

Sylvain Piqueux, David M. Kass, Daniel J. McCleese, John T. Schofield, Armin Kleinböhl, and Paul O. Hayne

Subjects

Thermal Emission Spectrometer, Polar night, Space and Planetary Science, Dust storm, Diurnal temperature variation, Equivalent latitude, Environmental science, Astronomy and Astrophysics, Martian polar ice caps, Mars Exploration Program, Atmosphere of Mars, Atmospheric sciences

Abstract

We present eight Mars Years of nearly continuous tracking of the CO2 seasonal cap edges from Mars Year (MY) 24 to 31 using Mars Global Surveyor (MGS) Thermal Emission Spectrometer (TES) and Mars Reconnaissance Orbiter (MRO) Mars Climate Sounder (MCS) thermal infrared data. Spatial and temporal resolutions are 1 pixel per degree and 10°Ls (aerocentric longitude of the Sun). The seasonal caps are defined as the regions where the diurnal radiometric temperature variations at ∼32 μm wavelength do not exceed 5 K. With this definition, terrains with small areal fraction of defrosted regolith able to experience measurable diurnal temperature cycles are not mapped as part of the cap. This technique is adequate to distinguish CO2 from H2O ices, and effective during the polar night or under low illumination conditions. The present analysis answers outstanding questions stemming from fragmented observations at visible wavelengths: (1) the previously sparsely documented growth of the North seasonal caps (160° < Ls < 270°) is shown to be repeatable within 1–2° equivalent latitude, and monotonic over the MY 24–31 time period; high repeatability is observed during the retreat of the caps in non-dusty years (∼1° or less equivalent latitude); (2) the MY 25 storm does not seem to have impacted the growth rate, maximal extents, or recession rate of the North seasonal caps, whereas the MY 28 dust storm clearly sped up the recession of the cap (∼2° smaller on average after the storm, during the recession, compared to other years); (3) during non-dusty years, the growth of the South seasonal cap (350° < Ls < 100°) presents noticeable variability (up to ∼4° equivalent latitude near Ls = 20°) with a maximum extent reached near Ls = 90°; (4) the retreat of the Southern seasonal cap (100° < Ls < 310°) exhibits large inter-annual variability, especially near 190° < Ls < 220°; (5) the recession of the MY 25 South seasonal cap is significantly accelerated during the equinox global dust storm, with surface temperatures suggesting increased patchiness or enhanced dust mantling on the CO2 ice. These results suggest that atmospheric temperatures and dust loading are the primary source of variability in an otherwise remarkably repeatable cycle of seasonal cap growth and recession.

Published

2015

11. Seasonal and diurnal variability of detached dust layers in the tropical Martian atmosphere

Author

James H. Shirley, R. John Wilson, W. A. Abdou, David M. Kass, Nicholas G. Heavens, Armin Kleinböhl, Daniel J. McCleese, and Morgan S. Johnson

Subjects

Tharsis Montes, Mars Exploration Program, Atmospheric model, Atmosphere of Mars, Atmospheric sciences, Atmosphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Dust storm, Climatology, Earth and Planetary Sciences (miscellaneous), Environmental science, Upwelling, Hadley cell

Abstract

Evidence for widespread nonuniform vertical mixing of dust in Mars's tropical atmosphere (in the form of features called “detached dust layers” or DDLs) is a challenge for atmospheric modeling. We characterize the seasonal, diurnal, and geographic variability of DDL activity in retrievals from observations by the Mars Climate Sounder onboard Mars Reconnaissance Orbiter. We find that dust injection above the boundary layer, which forms DDLs, is a spatially ubiquitous phenomenon in the tropics during the daytime, implying that it has a significant nontopographic component. DDL formation is more intense in northern spring and summer than in southern spring and summer but is still common when the zonal average dust distribution appears uniformly mixed. DDLs do not appear to follow the upwelling associated with Mars's Hadley circulation or the extant climatology of local dust storm activity in the tropics. Geographic variability in the nightside vertical dust distribution does not always correlate with the dayside vertical dust distribution, implying that there is spatial and seasonal variability in the efficiency of dust deposition/removal processes. Nighttime dust removal is especially efficient over the Tharsis Montes during northern spring and summer, which suggests some association between water ice clouds and removal. Intense injection combined with efficient removal results in a high amplitude of diurnal variability in the dust distribution at 15–30 km above the surface of the tropics during much of the Martian year.

Published

2014

12. Radiometric comparison of Mars Climate Sounder and Thermal Emission spectrometer measurements

Author

Joshua L. Bandfield, John T. Schofield, Michael J. Wolff, Daniel J. McCleese, and Michael D. Smith

Subjects

Martian, Thermal Emission Spectrometer, Space and Planetary Science, Nadir, Environmental science, Astronomy and Astrophysics, Mars Exploration Program, Spectral bands, Atmosphere of Mars, Albedo, Atmospheric temperature, Atmospheric sciences, Remote sensing

Abstract

Mars Climate Sounder (MCS) nadir oriented thermal infrared and solar channel measurements are com- pared with Thermal Emission Spectrometer (TES) measurements across multiple Mars years. Thermal infrared measurements were compared by convolving the TES data using the MCS spectral band passes. The MCS solar channel measurements were calibrated using Compact Reconnaissance Imaging Spectrom- eter for Mars observations to provide the proper gain factor (3.09 � 10 � 3 Ws r � 1 m � 2 lm � 1 ). The compar- isons of the datasets show that day and night surface and atmospheric temperatures are within 3 K over the course of 5 martian years, after accounting for the local time differences. Any potential interannual variations in global average temperature are masked by calibration and modeling uncertainties. Previous work attributed apparent interannual global surface and atmospheric temperature variations to major dust storm activity; however, this variation has since been attributed to a calibration error in the TES dataset that has been corrected. MCS derived Lambert albedos are slightly higher than TES measurements acquired over the same season and locations. Most of this difference can be attributed to the spectral response functions of MCS and TES. Consistent with previous work, global albedo is highly variable (� 6%) and this variability must be taken into account when determining long term global trends. Vertical aerosol distributions were also derived from the calibrated MCS visible channel limb measurements, demonstrating the utility of the MCS visible channel data for monitoring of aerosols.

Published

2013

13. The semidiurnal tide in the middle atmosphere of Mars

Author

Daniel J. McCleese, John T. Schofield, Armin Kleinböhl, David M. Kass, and R. John Wilson

Subjects

Martian, Atmospheric tide, Atmosphere of Mars, Mars Exploration Program, Atmospheric sciences, Physics::Geophysics, Atmosphere, Geophysics, Dust storm, Climatology, Physics::Space Physics, Thermal, Astrophysics::Solar and Stellar Astrophysics, General Earth and Planetary Sciences, Environmental science, Timekeeping on Mars, Astrophysics::Earth and Planetary Astrophysics, Physics::Atmospheric and Oceanic Physics

Abstract

[1] Atmospheric thermal tides are global oscillations in atmospheric fields that are subharmonics of a solar day. While atmospheric tides on Earth are mainly relevant in the upper atmosphere, on Mars, they dominate temperature variations and winds throughout the atmosphere. Observations and model simulations to date have suggested that the migrating diurnal tide is the predominant mode in the Martian atmosphere, and that the semidiurnal tide is only relevant in the tropical middle atmosphere during conditions of high dust loading. New comprehensive observations by the Mars Climate Sounder in a geometry that allows coverage of multiple local times show that the semidiurnal tide is a dominant response of the Martian atmosphere throughout the Martian year. The maximum semidiurnal amplitude of ~ 16 K is found at southern winter high latitudes, which makes it the largest tidal amplitude observed in the Martian middle atmosphere outside of dust storm conditions. The semidiurnal tide can be successfully modeled due to recent advances of Mars General Circulation Models (MGCMs) that include the radiatively active treatment of water ice clouds. Tidal forcing occurs through absorption of radiation by aerosols and points to the vertical structure of dust and clouds and their radiative effects as being essential for our understanding of the thermal structure and the general circulation of the Martian atmosphere. As with terrestrial GCMs trying to quantify mechanisms affecting climate, future Mars modeling efforts will require microphysical schemes to control aerosol distributions, and vertically and temporally resolved measurements of temperature and aerosols will be essential for their validation.

Published

2013

14. Infrared remote sounding of the middle atmosphere of venus from the pioneer orbiter

Author

Daniel J. McCleese, David J. Diner, John Theodore Houghton, L. S. Elson, S. E. Bradley, J. T. Schofield, Martha S. Hanner, J. V. Martonchik, Fredric W. Taylor, P. E. Reichley, Andrew P. Ingersoll, and J. Delderfield

Subjects

Multidisciplinary, biology, Equator, Venus, Atmospheric temperature, Atmospheric sciences, biology.organism_classification, law.invention, Latitude, Atmosphere, Atmosphere of Venus, Orbiter, Altitude, law, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Geology, Physics::Atmospheric and Oceanic Physics

Abstract

Orbiter infrared measurements of the Venus atmosphere in the 60- to 140-kilometer region show very small diurnal temperature differences near the cloud tops, increasing somewhat at higher levels. The seasonal (that is, equator to pole) contrasts are an order of magnitude larger, and the temperatures unexpectedly increase with increasing latitude below 80 kilometers. An isothermal layer at least two scale heights in vertical extent is found near the 100-kilometer altitude, where the temperature is about 175 K. Structure is present in the cloud temperature maps on a range of spatial scales. The most striking is at high latitude, where contrasts of nearly 50 K are observed between a cold circumpolar band and the region near the pole itself.

Published

2016

15. THE GLOBAL DISTRIBUTION OF WATER-VAPOR IN THE MIDDLE ATMOSPHERE OF VENUS

Author

Fredric W. Taylor, J. T. Schofield, and Daniel J. McCleese

Subjects

biology, Solar zenith angle, Astronomy and Astrophysics, Venus, biology.organism_classification, Atmospheric sciences, Atmosphere of Venus, Space and Planetary Science, Brightness temperature, Radiance, Mixing ratio, Environmental science, Water vapor, Optical depth

Abstract

Near-IR measurements are presented of the mean vertical and horizontal distribution of water vapor in the Venus clouds as measured by the Pioneer Venus Orbiter IR radiometer, and comparisons are made with previous data. Six thermal channels were used to generate several hundred thousand readings for determination of the mean mixing ratio. Averaging was performed as a function of the solar zenith angle, with profiles retrieved with a relaxation method applied to radiance data at 45 microns. Consideration was given to mean cloud models and temperature profiles obtained from the five temperature sounding channels scanning from 11.5-15 microns. Laboratory tests were effected to validate the transmission functions. The results included a maximum column abundances above the cloud optical depth in the early afternoon in the equatorial regions. Mixing ratio enhancement was highest on the dayside and at high altitudes, with a mean ratio of 0.0001 at a 40% uncertainty level. Day-to-day fluctuations in the pressure level at 11.5 microns was larger than 10%, far below the factors of 2-3 determined by other investigators.

Published

2016

16. Convective instability in the martian middle atmosphere

Author

John T. Schofield, James H. Shirley, Nicholas G. Heavens, Mark I. Richardson, Christopher C. Lee, David M. Kass, W. G. Lawson, Armin Kleinböhl, Daniel J. McCleese, and W. A. Abdou

Subjects

Martian, Atmosphere, Convective instability, Space and Planetary Science, Atmospheric instability, Northern Hemisphere, Astronomy and Astrophysics, Atmosphere of Mars, Gravity wave, Atmospheric temperature, Atmospheric sciences, Geology

Abstract

Dry convective instabilities in Mars’s middle atmosphere are detected and mapped using temperature retrievals from Mars Climate Sounder observations spanning 1.5 martian years. The instabilities are moderately frequent in the winter extratropics. The frequency and strength of middle atmospheric convective instability in the northern extratropics is significantly higher in MY 28 than in MY 29. This may have coupled with changes to the northern hemisphere mid-latitude and tropical middle atmospheric temperatures and contributed to the development of the 2007 global dust storm. We interpret these instabilities to be the result of gravity waves saturating within regions of low stability created by the thermal tides. Gravity wave saturation in the winter extratropics has been proposed to provide the momentum lacking in general circulation models to produce the strong dynamically-maintained temperature maximum at 1–2 Pa over the winter pole, so these observations could be a partial control on modeling experiments.

Published

2010

17. Intense polar temperature inversion in the middle atmosphere on Mars

Author

Nicholas G. Heavens, S. B. Calcutt, Nicholas A Teanby, Stephen R. Lewis, Richard W. Zurek, Armin Kleinböhl, W. G. Lawson, Fredric W. Taylor, Don Banfield, Oded Aharonson, Patrick G. J. Irwin, John T. Schofield, Mark I. Richardson, Peter L. Read, Daniel J. McCleese, David M. Kass, W. A. Abdou, Conway B. Leovy, and David A. Paige

Subjects

Martian, Atmosphere, Orbiter, Atmospheric circulation, law, Downwelling, General Earth and Planetary Sciences, Environmental science, Weather and climate, Hadley cell, Mars Exploration Program, Atmospheric sciences, law.invention

Abstract

Current understanding of weather, climate and global atmospheric circulation on Mars is incomplete, in particular at altitudes above about 30 km. General circulation models for Mars are similar to those developed for weather and climate forecasting on Earth and require more martian observations to allow testing and model improvements. However, the available measurements of martian atmospheric temperatures, winds, water vapour and airborne dust are generally restricted to the region close to the surface and lack the vertical resolution and global coverage that is necessary to shed light on the dynamics of Mars middle atmosphere at altitudes between 30 and 80 km (ref.7). Here we report high-resolution observations from the Mars Climate Sounder instrument on the Mars Reconnaissance Orbiter. These observations show an intense warming of the middle atmosphere over the south polar region in winter that is at least 10-20 K warmer than predicted by current model simulations. To explain this finding, we suggest that the atmospheric downwelling circulation over the pole, which is part of the equator-to-pole Hadley circulation, may be as much as 50 more vigorous than expected, with consequences for the cycles of water, dust and CO"2 that regulate the present-day climate on Mars. © 2008 Macmillan Publishers Limited.

Published

2008

18. Carbon dioxide snow clouds on Mars: South polar winter observations by the Mars Climate Sounder

Author

Armin Kleinböhl, Nicholas G. Heavens, Paul O. Hayne, David M. Kass, John T. Schofield, Daniel J. McCleese, and David A. Paige

Subjects

Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Atmosphere, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Emissivity, Astrophysics::Galaxy Astrophysics, Physics::Atmospheric and Oceanic Physics, Earth-Surface Processes, Water Science and Technology, Ecology, Paleontology, Forestry, Mars Exploration Program, Albedo, Snow, Geophysics, Space and Planetary Science, Mars Orbiter Laser Altimeter, Environmental science, Martian polar ice caps, Astrophysics::Earth and Planetary Astrophysics, Polar mesospheric clouds

Abstract

[1] We present south polar winter infrared observations from the Mars Climate Sounder (MCS) and test three hypotheses concerning the origins of “cold spots”: regions of anomalously low infrared brightness temperatures, which could be due to enrichment in non-condensable gases, low-emissivity surface frost, or optically thick CO2 clouds. Clouds and surface frosts have been historically difficult to distinguish, but the unique limb sounding capability of MCS reveals extensive tropospheric CO2clouds over the cold spots. We find that both clouds and surface deposits play a significant role in lowering the infrared emissivity of the seasonal ice cap, and the granular surface deposits are likely emplaced by snowfall. Surface temperatures indicate the polar winter atmosphere is enriched by a factor ∼5–7 in non-condensable gases relative to the annual average, consistent with earlier gamma ray spectrometer observations, but not enough to account for the low brightness temperatures. A large ∼500-km diameter cloud with visible optical depth ∼0.1–1.0 persists throughout winter over the south polar residual cap (SPRC). At latitudes 70–80°S, clouds and low emission regions are smaller and shorter-lived, probably corresponding to large-grained “channel 1” clouds observed by the Mars Orbiter Laser Altimeter. Snowfall over the SPRC imparts the lowest emissivity in the south polar region, which paradoxically tends to reduce net accumulation of seasonal CO2 by backscattering infrared radiation. This could be compensated by the observed anomalously high summertime albedo of the SPRC, which may be related to small grains preserved in a rapidly formed snow deposit.

Published

2012

19. The vertical distribution of dust in the Martian atmosphere during northern spring and summer: Observations by the Mars Climate Sounder and analysis of zonal average vertical dust profiles

Author

Armin Kleinböhl, Mark I. Richardson, W. A. Abdou, Daniel J. McCleese, P. M. Wolkenberg, Nicholas G. Heavens, David M. Kass, J. L. Benson, James H. Shirley, and John T. Schofield

Subjects

Martian, Atmospheric Science, Ecology, Opacity, Paleontology, Soil Science, Tropics, Forestry, Mars Exploration Program, Atmosphere of Mars, Aquatic Science, Radiative forcing, Oceanography, Atmospheric sciences, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Dust storm, Climatology, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, Earth-Surface Processes, Water Science and Technology

Abstract

[1] The vertical distribution of dust in Mars's atmosphere is a critical and poorly known input in atmospheric physical and chemical models and a source of insight into the lifting and transport of dust and general vertical mixing in the atmosphere. We investigate vertical profiles of dust opacity retrieved from limb observations by Mars Climate Sounder during the relatively dust-clear Martian northern summer of 2006–2007 (Ls = 111°–177°of Mars year (MY) 28) and Martian northern spring and summer of 2007–2008 (Ls = 0°–180° of MY 29). To represent local maxima in inferred mass mixing ratio in these profiles, we develop an empirical alternative to the classic “Conrath profile” for representing the vertical distribution of dust in the Martian atmosphere. We then assess the magnitude and variability of atmospheric dust loading, the depth of dust penetration during these seasons, and the impact of the observed vertical dust distribution on the radiative forcing of the circulation. During most of northern spring and summer, the dust mass mixing ratio in the tropics has a maximum at 15–25 km above the local surface (the high-altitude tropical dust maximum (HATDM)). The HATDM appears to have increased significantly in magnitude and altitude during middle to late northern summer of MY 29. The HATDM gradually decayed during late summer of MY 28. Interannual variability in the dust distribution during middle to late northern summer may be connected with known interannual variability in tropical dust storm activity.

Published

2011

20. Vertical distribution of dust in the Martian atmosphere during northern spring and summer: High-altitude tropical dust maximum at northern summer solstice

Author

P. M. Wolkenberg, David M. Kass, Nicholas G. Heavens, W. A. Abdou, James H. Shirley, Daniel J. McCleese, John T. Schofield, Armin Kleinböhl, Mark I. Richardson, and J. L. Benson

Subjects

Atmospheric Science, Ecology, Paleontology, Soil Science, Forestry, Storm, Mars Exploration Program, Atmosphere of Mars, Aquatic Science, Oceanography, Atmospheric sciences, Atmosphere, Mars general circulation model, Geophysics, Altitude, Space and Planetary Science, Geochemistry and Petrology, Dust storm, Climatology, Earth and Planetary Sciences (miscellaneous), Environmental science, Outflow, Earth-Surface Processes, Water Science and Technology

Abstract

[1] The vertical distribution of dust in Mars' atmosphere is a critical unknown in the simulation of its general circulation and a source of insight into the lifting and transport of dust. Zonal average vertical profiles of dust opacity retrieved by Mars Climate Sounder show that the vertical dust distribution is mostly consistent with Mars general circulation model (GCM) simulations in southern spring and summer but not in northern spring and summer. Unlike the GCM simulations, the mass mixing ratio of dust has a maximum at 15–25 km over the tropics during much of northern spring and summer: the high-altitude tropical dust maximum (HATDM). The HATDM has significant and characteristic longitudinal variability, which it maintains for time scales on the order of or greater than those on which advection, sedimentation, and vertical eddy diffusion would act to eliminate both the longitudinal and vertical inhomogeneity of the distribution. While outflow from dust storms is able to produce enriched layers of dust at altitudes much greater than 25 km, tropical dust storm activity during the period in which the HATDM occurs is likely too rare to support the HATDM. Instead, the lifting of dust by mesoscale circulations over topography, pseudomoist convection due to the solar heating of dust, and scavenging of dust by water ice are all possible drivers of the HATDM.

Published

2011

21. Structure and dynamics of the Martian lower and middle atmosphere as observed by the Mars Climate Sounder: Seasonal variations in zonal mean temperature, dust and water ice aerosols

Author

Daniel J. McCleese, Armin Kleinböhl, Fredric W. Taylor, Richard W. Zurek, Pgj Irwin, Joshua L. Bandfield, S. B. Calcutt, Peter L. Read, John T. Schofield, James H. Shirley, David M. Kass, W. A. Abdou, Stephen R. Lewis, Nicholas G. Heavens, Mark I. Richardson, David A. Paige, and Nicholas A Teanby

Subjects

Martian, Atmospheric Science, Ecology, Paleontology, Soil Science, Forestry, Atmosphere of Mars, Mars Exploration Program, Aquatic Science, Oceanography, Atmospheric sciences, Aerosol, Atmosphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Polar vortex, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, Martian polar ice caps, Earth-Surface Processes, Water Science and Technology

Abstract

The first Martian year and a half of observations by the Mars Climate Sounder aboard the Mars Reconnaissance Orbiter has revealed new details of the thermal structure and distributions of dust and water ice in the atmosphere. The Martian atmosphere is shown in the observations by the Mars Climate Sounder to vary seasonally between two modes: a symmetrical equinoctial structure with middle atmosphere polar warming and a solstitial structure with an intense middle atmosphere polar warming overlying a deep winter polar vortex. The dust distribution, in particular, is more complex than appreciated before the advent of these high (∼5 km) vertical resolution observations, which extend from near the surface to above 80 km and yield 13 dayside and 13 nightside pole-to-pole cross sections each day. Among the new features noted is a persistent maximum in dust mass mixing ratio at 15-25 km above the surface (at least on the nightside) during northern spring and summer. The water ice distribution is very sensitive to the diurnal and seasonal variation of temperature and is a good tracer of the vertically propagating tide. Copyright 2010 by the American Geophysical Union.

Published

2010

22. Mars' south polar hood as observed by the Mars Climate Sounder

Author

Daniel J. McCleese, Armin Kleinböhl, Fredric W. Taylor, David M. Kass, J. L. Benson, and John T. Schofield

Subjects

Atmospheric Science, Ice cloud, Daytime, Ecology, Paleontology, Soil Science, Forestry, Mars Exploration Program, Aquatic Science, Oceanography, Atmospheric temperature, Atmospheric sciences, Latitude, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Longitude, Optical depth, Geology, Water vapor, Earth-Surface Processes, Water Science and Technology

Abstract

[1] We have used observations from the Mars Climate Sounder to investigate south polar hood water ice clouds (at 12 μm), including the first systematic examination of the vertical (5 km resolution) and nighttime structure. We find that the structure and evolution of the polar hood is controlled more strongly by atmospheric temperature variations than by intrinsic fluctuations in water vapor abundance. The clouds form as a belt during LS = 10°–70° (phase 1) and LS = 100°–200° (phase 2). During phase 1, the cloud belt extends over a wide latitude range, between 30°S and 75°S with a visible column optical depth between 0.075 and 0.15. The cloud belt then evaporates as temperatures warm. During phase 2, the cloud belt reappears due to an increase in water vapor as a partial band of low-opacity clouds south of the Tharsis region and eventually becomes continuous in longitude, with a visible column opacity between 0.125 and 0.25. As the southern spring equinox approaches, the cloud belt shifts southward, following the seasonal cap edge. From LS = 140° to LS = 200°, the daytime belt lies about 15° farther south than the nighttime belt, due to tidally driven diurnal temperature differences. The vertical structure of the cloud belt is consistent within and between the two seasonal phases and is characterized by a thick lower cloud deck and an upper layer whose altitude shifts between the nighttime and daytime because of thermal tidal control of the condensation altitudes. Overall, the southern polar hood is observed to rapidly form and dissipate as the temperature crosses the saturation point of water vapor.

Published

2010

23. Water ice clouds over the Martian tropics during northern summer

Author

Daniel J. McCleese, David M. Kass, W. A. Abdou, Armin Kleinböhl, James H. Shirley, Mark I. Richardson, P. M. Wolkenberg, Nicholas G. Heavens, J. L. Benson, and John T. Schofield

Subjects

Martian, Ice cloud, Tropics, Mars Exploration Program, Atmospheric model, Atmospheric sciences, complex mixtures, Atmosphere, Geophysics, Altitude, General Earth and Planetary Sciences, Environmental science, Martian polar ice caps, sense organs

Abstract

[1] Atmospheric models suggest that infrared heating due to water ice clouds over the tropics of Mars during early northern summer has a significant impact on the thermal structure of the tropics at cloud level and of the middle atmosphere near the south pole. Retrievals from limb observations by the Mars Climate Sounder on Mars Reconnaissance Orbiter during early northern summer show that water ice clouds over the northern tropics are thinner and higher than in published model results. Later in this season, the latitudinal extent, apparent mass mixing ratio (and infrared heating rate), and altitude of nighttime tropical clouds significantly increase, reaching a maximum just before northern fall equinox. Published model results do not show this transition. By underestimating the altitude at which water ice clouds form, models also may underestimate the intensity of the meridional circulation at higher altitudes in the tropics during northern summer.

Published

2010

24. Mars Climate Sounder limb profile retrieval of atmospheric temperature, pressure, and dust and water ice opacity

Author

Armin Kleinböhl, Fredric W. Taylor, Nicholas A Teanby, C. Backus, Bhaswar Sen, W. A. Abdou, Mark I. Richardson, John T. Schofield, James H. Shirley, David M. Kass, W. Gregory Lawson, and Daniel J. McCleese

Subjects

Martian, Atmospheric Science, Radiometer, Ecology, Opacity, Paleontology, Soil Science, Forestry, Atmosphere of Mars, Mars Exploration Program, Aquatic Science, Oceanography, Atmospheric sciences, Atmospheric temperature, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Radiative transfer, Environmental science, Water vapor, Earth-Surface Processes, Water Science and Technology, Remote sensing

Abstract

The Mars Climate Sounder (MCS) onboard the Mars Reconnaissance Orbiter is the latest of a series of investigations devoted to improving the understanding of current Martian climate. MCS is a nine-channel passive midinfrared and far-infrared filter radiometer designed to measure thermal emission in limb and on-planet geometries from which vertical profiles of atmospheric temperature, water vapor, dust, and condensates can be retrieved. Here we describe the algorithm that is used to retrieve atmospheric profiles from MCS limb measurements for delivery to the Planetary Data System. The algorithm is based on a modified Chahine method and uses a fast radiative transfer scheme based on the Curtis-Godson approximation. It retrieves pressure and vertical profiles of atmospheric temperature, dust opacity, and water ice opacity. Water vapor retrievals involve a different approach and will be reported separately. Pressure can be retrieved to a precision of 1–2% and is used to establish the vertical coordinate. Temperature profiles are retrieved over a range from 5–10 to 80–90 km altitude with a typical altitude resolution of 4–6 km and a precision between 0.5 and 2 K over most of this altitude range. Dust and water ice opacity profiles also achieve vertical resolutions of about 5 km and typically have precisions of 10^(−4)–10^(−5) km^(−1) at 463 cm^(−1) and 843 cm^(−1), respectively. Examples of temperature profiles as well as dust and water ice opacity profiles from the first year of the MCS mission are presented, and atmospheric features observed during periods employing different MCS operational modes are described. An intercomparison with historical temperature measurements from the Mars Global Surveyor mission shows good agreement.

Published

2009

25. Thermal tides in the Martian middle atmosphere as seen by the Mars Climate Sounder

Author

Christopher C. Lee, Anthony D. Toigo, W. G. Lawson, Daniel J. McCleese, David M. Kass, John T. Schofield, Conway B. Leovy, Richard W. Zurek, Nicholas G. Heavens, Don Banfield, Mark I. Richardson, Armin Kleinböhl, and Fredric W. Taylor

Subjects

Martian, Atmospheric Science, Mesoscale convective system, Ecology, Opacity, Paleontology, Soil Science, Forestry, Atmosphere of Mars, Mars Exploration Program, Aquatic Science, Oceanography, Atmospheric sciences, Article, Latitude, Atmosphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Climatology, Thermal, Earth and Planetary Sciences (miscellaneous), Environmental science, Earth-Surface Processes, Water Science and Technology

Abstract

The first systematic observations of the middle atmosphere of Mars (35–80km) with the Mars Climate Sounder (MCS) show dramatic patterns of diurnal thermal variation, evident in retrievals of temperature and water ice opacity. At the time of writing, the data set of MCS limb retrievals is sufficient for spectral analysis within a limited range of latitudes and seasons. This analysis shows that these thermal variations are almost exclusively associated with a diurnal thermal tide. Using a Martian general circulation model to extend our analysis, we show that the diurnal thermal tide dominates these patterns for all latitudes and all seasons.

Published

2009

26. Mars Climate Sounder: An investigation of thermal and water vapor structure, dust and condensate distributions in the atmosphere, and energy balance of the polar regions

Author

David M. Kass, Peter L. Read, Richard W. Zurek, Daniel J. McCleese, John T. Schofield, S. B. Calcutt, David A. Paige, Fredric W. Taylor, Marc C. Foote, and Conway B. Leovy

Subjects

Atmospheric Science, Meteorology, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, law.invention, Atmosphere, Orbiter, Geochemistry and Petrology, law, Martian surface, Earth and Planetary Sciences (miscellaneous), Weather satellite, Earth-Surface Processes, Water Science and Technology, Ecology, Paleontology, Forestry, Mars Exploration Program, Atmosphere of Mars, Atmospheric temperature, Geophysics, Space and Planetary Science, Environmental science, Water vapor

Abstract

Against a backdrop of intensive exploration of the Martian surface environment, intehded to lead to human exploration, some aspects of the modern climate and the meteorology of Mars remain relatively unexplored. In particular, there is a need for detailed measurements of the vertical profiles of atmospheric temperature, water vapor, dust, and condensates to understand the intricately related processes upon which the surface conditions, and those encountered during descent by landers, depend. The most important of these missing data are accurate and extensive temperature measurements with high vertical resolution. The Mars Climate Sounder experiment on the 2005 Mars Reconnaissance Orbiter, described here, is the latest attempt to characterize the Martian atmosphere with the sort of coverage and precision achieved by terrestrial weather satellites. If successful, it is expected to lead to corresponding improvements in our understanding of meteorological phenomena and to enable improved general circulation models of the Martian atmosphere for climate studies on a range of timescales. Copyright 2007 by the American Geophysical Union.

Published

2007

27. On the orbital forcing of Martian water and CO2cycles: A general circulation model study with simplified volatile schemes

Author

Michael Mischna, R. John Wilson, Daniel J. McCleese, and Mark I. Richardson

Subjects

Atmospheric Science, Soil Science, Atmospheric model, Aquatic Science, Oceanography, Surface pressure, Atmospheric sciences, Physics::Geophysics, Atmosphere, Mars general circulation model, Geophysical fluid dynamics, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Physics::Atmospheric and Oceanic Physics, Earth-Surface Processes, Water Science and Technology, Martian, Ecology, Paleontology, Forestry, Mars Exploration Program, Geophysics, Space and Planetary Science, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Water vapor, Geology

Abstract

[1] Variations in the Martian water and CO2 cycles with changes in orbital and rotational parameters are examined using the Geophysical Fluid Dynamics Laboratory Mars General Circulation Model. The model allows for arbitrary specification of obliquity, eccentricity, and argument of perihelion as well as the position and thickness of surface ice. Exchange of CO2 between the surface and atmosphere is modeled, generating seasonal cycles of surface ice and surface pressure. Water is allowed to exchange between the surface and atmosphere, cloud formation is treated, and both cloud and vapor are transported by modeled winds and diffusion. Exchange of water and CO2 with the subsurface is not allowed, and radiative effects of water vapor and clouds are not treated. The seasonal cycle of CO2 is found to become more extreme at high obliquity, as suggested by simple heat balance models. Maximum pressures remain largely the same, but the minima decrease substantially as more CO2 condenses in the more extensive polar night. Vapor and cloud abundances increase dramatically with obliquity. The stable location for surface ice moves equatorward with increasing obliquity, such that by 45° obliquity, water ice is stable in the tropics only. Ice is not spatially uniform, but rather found preferentially in regions of high thermal inertia or high topography. Eccentricity and argument of perihelion can provide a second-order modification to the distribution of surface ice by altering the temporal distribution of insolation at the poles. Further model simulations reveal the robustness of these distributions for a variety of initial conditions. Our findings shed light on the nature of near-surface, ice-rich deposits at midlatitudes and low-latitudes on Mars.

Published

2003

28. Atmosphere and climate studies of Mars using the Mars Observer pressure modulator infrared radiometer

Author

John T. Schofield, Daniel J. McCleese, Conway B. Leovy, Richard W. Zurek, R. D. Haskins, David A. Paige, and Fredric W. Taylor

Subjects

Earth's energy budget, Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Atmosphere, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Physics::Atmospheric and Oceanic Physics, Earth-Surface Processes, Water Science and Technology, Remote sensing, Atmospheric sounding, Ecology, Paleontology, Forestry, Mars Exploration Program, Atmosphere of Mars, Atmospheric temperature, Geophysics, Space and Planetary Science, Mars Orbiter Laser Altimeter, Physics::Space Physics, Environmental science, Timekeeping on Mars, Astrophysics::Earth and Planetary Astrophysics

Abstract

Studies of the climate and atmosphere of Mars are limited at present by a lack of meteorological data having systematic global coverage with good horizontal and vertical resolution. The Mars Observer spacecraft in a low, nearly circular, polar orbit will provide an excellent platform for acquiring the data needed to advance significantly our understanding of the Martian atmosphere and its remarkable variability. The Mars Observer pressure modulator infrared radiometer (PMIRR) is a nine-channel limb and nadir scanning atmospheric sounder which will observe the atmosphere of Mars globally from 0 to 80 km for a full Martian year. PMIRR employs narrow-band radiometric channels and two pressure modulation cells to measure atmospheric and surface emission in the thermal infrared. PMIRR infrared and visible measurements will be combined to determine the radiative balance of the polar regions, where a sizeable fraction of the global atmospheric mass annually condenses onto and sublimes from the surface. Derived meteorological fields, including diabatic heating and cooling and the vertical variation of horizontal winds, are computed from the globally mapped fields retrieved from PMIRR data.

Published

1992

29. COMPARATIVE ASPECTS OF VENUS AND TERRESTRIAL METEOROLOGY

Author

Fredric W. Taylor, L. S. Elson, Daniel J. McCleese, and David J. Diner

Subjects

Atmospheric Science, biology, Meteorology, Venus, Atmospheric sciences, Atmospheric temperature, biology.organism_classification, Physics::History of Physics, Astrobiology, Mesosphere, Atmosphere of Venus, Atmosphere of Earth, Aspects of Venus, Planet, Brightness temperature, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Physics::Atmospheric and Oceanic Physics, Geology

Abstract

The observations and measurements made by Pioneer Venus orbiters are presented in terms of comparison of Venus and terrestrial meteorology. Although the temperature-pressure profiles of the two planets differ at lower altitudes, the temperatures are similar over their common range of pressures except for a much cooler mesosphere on Venus. The additional similarities between the earth and Venus relate to the warm polar stratospheres and the zonally-averaged energy budgets of the two planets. A difference in the mean radiation budgets for Venus is the relative smallness of the upward and downward thermal flux components. It is noted that the observed similarities reflect common mechanisms despite the difference in the dynamical regimes of the two planets.

Published

1981

30. Remote Detection of Gases by Gas Correlation Spectroradiometry

Author

Jack S. Margolis, Daniel J. McCleese, and J. V. Martonchik

Subjects

Atmospheric sounding, Radiometer, Geosynchronous orbit, Atmospheric sciences, Mesosphere, Atmosphere, Spectroradiometer, Physics::Space Physics, Mixing ratio, Environmental science, Astrophysics::Earth and Planetary Astrophysics, High-altitude balloon, Physics::Atmospheric and Oceanic Physics, Remote sensing

Abstract

We will discuss here the application of a pressure modulated radiometer (PMR) to the remote sensing of trace amounts of gases in the atmosphere as well as to the direct measurement of upper atmosphere winds. The range of altitudes which may be covered with this device vary from ground level up to the lower mesosphere. Gas concentrations corresponding to a mixing ratio of 1 ppm in a 10-meter column can be sensed from geosynchronous orbit. Even higher sensitivity can be achieved at shorter distances. The PMR has an extensive history of flight testing and has been used in earth meteorological satellites, numerous high altitude balloon flights and planetary exploration spacecraft.

Published

1983

31. Structure and meteorology of the middle atmosphere of Venus: Infrared remote sensing from the Pioneer Orbiter

Author

J. Delderfield, John V. Martonchik, John C. Gille, Reinhard Beer, J. Leung, M. T. Chahine, David J. Diner, Daniel J. McCleese, R. D. Haskins, Crofton B. Farmer, S. P. Bradley, Fredric W. Taylor, Lucien Froidevaux, John T. Schofield, P. E. Reichley, M. T. Coffey, and L. S. Elson

Subjects

Atmospheric Science, Meteorology, Equator, Soil Science, Venus, Aquatic Science, Oceanography, Atmospheric sciences, law.invention, Atmosphere, Atmosphere of Venus, Orbiter, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Stratosphere, Earth-Surface Processes, Water Science and Technology, Ecology, biology, Paleontology, Forestry, Atmospheric temperature, biology.organism_classification, Geophysics, Space and Planetary Science, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Thermosphere, Geology

Abstract

The results of the Pioneer Venus orbiter radiometric temperature-sounding experiment are presented with examples of each of the primary data products. The measured temperature field is used to model the dynamics of the middle atmosphere from 60 to 140 km, and the thermal and solar fluxes are used to calculate the planetary radiation budget. The data for the diurnal variation of temperature at a given height show fairly small amplitudes up to an altitude of about 95 km, above which the day to night contrast increases rapidly with height. At the equator the dependence of temperature in the stratosphere on solar longitude is dominated by a wave number 2 solar tide with an amplitude of about 10 K. The equator to pole gradients are larger than expected, and the stratosphere is typically 15 to 20 K warmer at the pole than at the equator. The most significant discovery concerning the cloud morphology is a dipole structure consisting of two clearings in the cloud at locations straddling the pole and rotating around it every 2.7 days.

Published

1980