Your search keyword '"Limaye, Sanjay S."' showing total 29 results

1. The CO2 profile and analytical model for the Pioneer Venus Large Probe neutral mass spectrometer

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Mogul, Rakesh, Limaye, Sanjay S., and Way, Michael J.

Abstract

We present a significantly updated CO2 altitude profile for Venus (64.2–0.9 km) and provide support for a potential deep lower atmospheric haze of particles (≤17 km). We extracted this information by developing a new analytical model for mass spectra obtained by the Pioneer Venus Large Probe (PVLP) Neutral Mass Spectrometer (LNMS). Our model accounts for changes in LNMS configuration and output during descent and enables the disentanglement of isobaric species via a data fitting routine that adjusts for mass-dependent changes in peak shape. The model yields CO2 in units of density (kg m−3), isotope ratios for 13C/12C and 18O/16O, and 14 measures of CO2 density across 55.4–0.9 km, which represents the most complete altitude profile for CO2 at ≤60 km to date. The CO2 density profile is also consistent with the pressure, temperature, and volumetric gas measurements from the PVLP and VeNeRa spacecraft. Nominal and low-noise operations for the LNMS mass analyzer are supported by the behaviors (e.g., ionization yields, fragmentation yields, and peak shapes) of several internal standards (e.g., CH3+, CH4+, 40Ar+, 136Xe2+, and 136Xe+), which were tracked across the descent. Lastly, our review of the CO2 profile and LNMS spectra reveals hitherto unreported partial and rapidly clearing clogs of the inlet in the lower atmosphere, along with several ensuing data spikes at multiple masses. Together, these observations suggest that atmospheric intake was impacted by particles at ≤17 km and that rapid particle degradation at the inlet yielded a temporary influx of mass signals into the LNMS.

Published

2023

2. The CO2 profile and analytical model for the Pioneer Venus Large Probe neutral mass spectrometer

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Mogul, Rakesh, Limaye, Sanjay S., and Way, Michael J.

Abstract

We present a significantly updated CO2 altitude profile for Venus (64.2–0.9 km) and provide support for a potential deep lower atmospheric haze of particles (≤17 km). We extracted this information by developing a new analytical model for mass spectra obtained by the Pioneer Venus Large Probe (PVLP) Neutral Mass Spectrometer (LNMS). Our model accounts for changes in LNMS configuration and output during descent and enables the disentanglement of isobaric species via a data fitting routine that adjusts for mass-dependent changes in peak shape. The model yields CO2 in units of density (kg m−3), isotope ratios for 13C/12C and 18O/16O, and 14 measures of CO2 density across 55.4–0.9 km, which represents the most complete altitude profile for CO2 at ≤60 km to date. The CO2 density profile is also consistent with the pressure, temperature, and volumetric gas measurements from the PVLP and VeNeRa spacecraft. Nominal and low-noise operations for the LNMS mass analyzer are supported by the behaviors (e.g., ionization yields, fragmentation yields, and peak shapes) of several internal standards (e.g., CH3+, CH4+, 40Ar+, 136Xe2+, and 136Xe+), which were tracked across the descent. Lastly, our review of the CO2 profile and LNMS spectra reveals hitherto unreported partial and rapidly clearing clogs of the inlet in the lower atmosphere, along with several ensuing data spikes at multiple masses. Together, these observations suggest that atmospheric intake was impacted by particles at ≤17 km and that rapid particle degradation at the inlet yielded a temporary influx of mass signals into the LNMS.

Published

2023

3. The CO2 profile and analytical model for the Pioneer Venus Large Probe neutral mass spectrometer

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Mogul, Rakesh, Limaye, Sanjay S., and Way, Michael J.

Abstract

We present a significantly updated CO2 altitude profile for Venus (64.2–0.9 km) and provide support for a potential deep lower atmospheric haze of particles (≤17 km). We extracted this information by developing a new analytical model for mass spectra obtained by the Pioneer Venus Large Probe (PVLP) Neutral Mass Spectrometer (LNMS). Our model accounts for changes in LNMS configuration and output during descent and enables the disentanglement of isobaric species via a data fitting routine that adjusts for mass-dependent changes in peak shape. The model yields CO2 in units of density (kg m−3), isotope ratios for 13C/12C and 18O/16O, and 14 measures of CO2 density across 55.4–0.9 km, which represents the most complete altitude profile for CO2 at ≤60 km to date. The CO2 density profile is also consistent with the pressure, temperature, and volumetric gas measurements from the PVLP and VeNeRa spacecraft. Nominal and low-noise operations for the LNMS mass analyzer are supported by the behaviors (e.g., ionization yields, fragmentation yields, and peak shapes) of several internal standards (e.g., CH3+, CH4+, 40Ar+, 136Xe2+, and 136Xe+), which were tracked across the descent. Lastly, our review of the CO2 profile and LNMS spectra reveals hitherto unreported partial and rapidly clearing clogs of the inlet in the lower atmosphere, along with several ensuing data spikes at multiple masses. Together, these observations suggest that atmospheric intake was impacted by particles at ≤17 km and that rapid particle degradation at the inlet yielded a temporary influx of mass signals into the LNMS.

Published

2023

4. The CO2 profile and analytical model for the Pioneer Venus Large Probe neutral mass spectrometer

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Mogul, Rakesh, Limaye, Sanjay S., and Way, Michael J.

Abstract

We present a significantly updated CO2 altitude profile for Venus (64.2–0.9 km) and provide support for a potential deep lower atmospheric haze of particles (≤17 km). We extracted this information by developing a new analytical model for mass spectra obtained by the Pioneer Venus Large Probe (PVLP) Neutral Mass Spectrometer (LNMS). Our model accounts for changes in LNMS configuration and output during descent and enables the disentanglement of isobaric species via a data fitting routine that adjusts for mass-dependent changes in peak shape. The model yields CO2 in units of density (kg m−3), isotope ratios for 13C/12C and 18O/16O, and 14 measures of CO2 density across 55.4–0.9 km, which represents the most complete altitude profile for CO2 at ≤60 km to date. The CO2 density profile is also consistent with the pressure, temperature, and volumetric gas measurements from the PVLP and VeNeRa spacecraft. Nominal and low-noise operations for the LNMS mass analyzer are supported by the behaviors (e.g., ionization yields, fragmentation yields, and peak shapes) of several internal standards (e.g., CH3+, CH4+, 40Ar+, 136Xe2+, and 136Xe+), which were tracked across the descent. Lastly, our review of the CO2 profile and LNMS spectra reveals hitherto unreported partial and rapidly clearing clogs of the inlet in the lower atmosphere, along with several ensuing data spikes at multiple masses. Together, these observations suggest that atmospheric intake was impacted by particles at ≤17 km and that rapid particle degradation at the inlet yielded a temporary influx of mass signals into the LNMS.

Published

2023

5. The CO2 profile and analytical model for the Pioneer Venus Large Probe neutral mass spectrometer

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Mogul, Rakesh, Limaye, Sanjay S., and Way, Michael J.

Abstract

We present a significantly updated CO2 altitude profile for Venus (64.2–0.9 km) and provide support for a potential deep lower atmospheric haze of particles (≤17 km). We extracted this information by developing a new analytical model for mass spectra obtained by the Pioneer Venus Large Probe (PVLP) Neutral Mass Spectrometer (LNMS). Our model accounts for changes in LNMS configuration and output during descent and enables the disentanglement of isobaric species via a data fitting routine that adjusts for mass-dependent changes in peak shape. The model yields CO2 in units of density (kg m−3), isotope ratios for 13C/12C and 18O/16O, and 14 measures of CO2 density across 55.4–0.9 km, which represents the most complete altitude profile for CO2 at ≤60 km to date. The CO2 density profile is also consistent with the pressure, temperature, and volumetric gas measurements from the PVLP and VeNeRa spacecraft. Nominal and low-noise operations for the LNMS mass analyzer are supported by the behaviors (e.g., ionization yields, fragmentation yields, and peak shapes) of several internal standards (e.g., CH3+, CH4+, 40Ar+, 136Xe2+, and 136Xe+), which were tracked across the descent. Lastly, our review of the CO2 profile and LNMS spectra reveals hitherto unreported partial and rapidly clearing clogs of the inlet in the lower atmosphere, along with several ensuing data spikes at multiple masses. Together, these observations suggest that atmospheric intake was impacted by particles at ≤17 km and that rapid particle degradation at the inlet yielded a temporary influx of mass signals into the LNMS.

Published

2023

6. The CO$_2$ Profile and Analytical Model for the Pioneer Venus Large Probe Neutral Mass Spectrometer

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael. J., Mogul, Rakesh, Limaye, Sanjay S., and Way, Michael. J.

Abstract

We present a significantly updated CO$_2$ altitude profile for Venus (64.2-0.9 km) and provide support for a potential deep lower atmospheric haze of particles (17 km and lower). We extracted this information by developing a new analytical model for mass spectra obtained by the Pioneer Venus Large Probe (PVLP) Neutral Mass Spectrometer (LNMS). Our model accounts for changes in LNMS configuration and output during descent and enables the disentanglement of isobaric species via a data fitting routine that adjusts for mass-dependent changes in peak shape. The model yields CO$_2$ in units of density (kg m-3), isotope ratios for $^{13}$C/$^{12}$C and $^{18}$O/$^{16}$O, and 14 measures of CO$_2$ density across 55.4-0.9 km, which represents the most complete altitude profile for CO$_2$ at 60 km towards the surface to date. The CO$_2$ density profile is also consistent with the pressure, temperature, and volumetric gas measurements from the PVLP and VeNeRa spacecraft. Nominal and low-noise operations for the LNMS mass analyzer are supported by the behaviors (e.g., ionization yields, fragmentation yields, and peak shapes) of several internal standards (e.g., CH$^{3+}$, CH$^{4+}$, $^{40}$Ar$^+$, $^{136}$Xe$^{2+}$, and $^{136}$Xe$^+$), which were tracked across the descent. Lastly, our review of the CO$_2$ profile and LNMS spectra reveals hitherto unreported partial and rapidly clearing clogs of the inlet in the lower atmosphere, along with several ensuing data spikes at multiple masses. Together, these observations suggest that atmospheric intake was impacted by particles at 17 km (and lower) and that rapid particle degradation at the inlet yielded a temporary influx of mass signals into the LNMS., Comment: Accepted, Nov. 2022

Published

2022

7. Venus' Mass Spectra Show Signs of Disequilibria in the Middle Clouds

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Cordova, Jaime A., Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., and Cordova, Jaime A.

Abstract

We present a re-examination of mass spectral data obtained from the Pioneer Venus Large Probe Neutral Mass Spectrometer. Our interpretations of differing trace chemical species are suggestive of redox disequilibria in Venus' middle clouds. Assignments to the data (at 51.3 km) include phosphine, hydrogen sulfide, nitrous acid, nitric acid, carbon monoxide, hydrochloric acid, hydrogen cyanide, ethane, and potentially ammonia, chlorous acid, and several tentative PxOy species. All parent ions were predicated upon assignment of corresponding fragmentation products, isotopologues, and atomic species. The data reveal parent ions at varying oxidation states, implying the presence of reducing power in the clouds, and illuminating the potential for chemistries yet to be discovered. When considering the hypothetical habitability of Venus' clouds, the assignments reveal a potential signature of anaerobic phosphorus metabolism (phosphine), an electron donor for anoxygenic photosynthesis (nitrite), and major constituents of the nitrogen cycle (nitrate, nitrite, ammonia, and N2).

Published

2021

8. Venus' Mass Spectra Show Signs of Disequilibria in the Middle Clouds

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Cordova, Jaime A., Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., and Cordova, Jaime A.

Abstract

We present a re-examination of mass spectral data obtained from the Pioneer Venus Large Probe Neutral Mass Spectrometer. Our interpretations of differing trace chemical species are suggestive of redox disequilibria in Venus' middle clouds. Assignments to the data (at 51.3 km) include phosphine, hydrogen sulfide, nitrous acid, nitric acid, carbon monoxide, hydrochloric acid, hydrogen cyanide, ethane, and potentially ammonia, chlorous acid, and several tentative PxOy species. All parent ions were predicated upon assignment of corresponding fragmentation products, isotopologues, and atomic species. The data reveal parent ions at varying oxidation states, implying the presence of reducing power in the clouds, and illuminating the potential for chemistries yet to be discovered. When considering the hypothetical habitability of Venus' clouds, the assignments reveal a potential signature of anaerobic phosphorus metabolism (phosphine), an electron donor for anoxygenic photosynthesis (nitrite), and major constituents of the nitrogen cycle (nitrate, nitrite, ammonia, and N2).

Published

2021

9. Venus' Mass Spectra Show Signs of Disequilibria in the Middle Clouds

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Cordova, Jaime A., Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., and Cordova, Jaime A.

Abstract

We present a re-examination of mass spectral data obtained from the Pioneer Venus Large Probe Neutral Mass Spectrometer. Our interpretations of differing trace chemical species are suggestive of redox disequilibria in Venus' middle clouds. Assignments to the data (at 51.3 km) include phosphine, hydrogen sulfide, nitrous acid, nitric acid, carbon monoxide, hydrochloric acid, hydrogen cyanide, ethane, and potentially ammonia, chlorous acid, and several tentative PxOy species. All parent ions were predicated upon assignment of corresponding fragmentation products, isotopologues, and atomic species. The data reveal parent ions at varying oxidation states, implying the presence of reducing power in the clouds, and illuminating the potential for chemistries yet to be discovered. When considering the hypothetical habitability of Venus' clouds, the assignments reveal a potential signature of anaerobic phosphorus metabolism (phosphine), an electron donor for anoxygenic photosynthesis (nitrite), and major constituents of the nitrogen cycle (nitrate, nitrite, ammonia, and N2).

Published

2021

10. Venus' Mass Spectra Show Signs of Disequilibria in the Middle Clouds

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Cordova, Jaime A., Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., and Cordova, Jaime A.

Abstract

We present a re-examination of mass spectral data obtained from the Pioneer Venus Large Probe Neutral Mass Spectrometer. Our interpretations of differing trace chemical species are suggestive of redox disequilibria in Venus' middle clouds. Assignments to the data (at 51.3 km) include phosphine, hydrogen sulfide, nitrous acid, nitric acid, carbon monoxide, hydrochloric acid, hydrogen cyanide, ethane, and potentially ammonia, chlorous acid, and several tentative PxOy species. All parent ions were predicated upon assignment of corresponding fragmentation products, isotopologues, and atomic species. The data reveal parent ions at varying oxidation states, implying the presence of reducing power in the clouds, and illuminating the potential for chemistries yet to be discovered. When considering the hypothetical habitability of Venus' clouds, the assignments reveal a potential signature of anaerobic phosphorus metabolism (phosphine), an electron donor for anoxygenic photosynthesis (nitrite), and major constituents of the nitrogen cycle (nitrate, nitrite, ammonia, and N2).

Published

2021

11. Venus' Mass Spectra Show Signs of Disequilibria in the Middle Clouds

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., Cordova, Jaime A., Mogul, Rakesh, Limaye, Sanjay S., Way, Michael J., and Cordova, Jaime A.

Abstract

We present a re-examination of mass spectral data obtained from the Pioneer Venus Large Probe Neutral Mass Spectrometer. Our interpretations of differing trace chemical species are suggestive of redox disequilibria in Venus' middle clouds. Assignments to the data (at 51.3 km) include phosphine, hydrogen sulfide, nitrous acid, nitric acid, carbon monoxide, hydrochloric acid, hydrogen cyanide, ethane, and potentially ammonia, chlorous acid, and several tentative PxOy species. All parent ions were predicated upon assignment of corresponding fragmentation products, isotopologues, and atomic species. The data reveal parent ions at varying oxidation states, implying the presence of reducing power in the clouds, and illuminating the potential for chemistries yet to be discovered. When considering the hypothetical habitability of Venus' clouds, the assignments reveal a potential signature of anaerobic phosphorus metabolism (phosphine), an electron donor for anoxygenic photosynthesis (nitrite), and major constituents of the nitrogen cycle (nitrate, nitrite, ammonia, and N2).

Published

2021

12. How waves and turbulence maintain the super-rotation of Venus' atmosphere

Author

Horinouchi, Takeshi, Hayashi, Yoshi-Yuki, Watanabe, Shigeto, Yamada, Manabu, Yamazaki, Atsushi, Kouyama, Toru, Taguchi, Makoto, Fukuhara, Tetsuya, Takagi, Masahiro, Ogohara, Kazunori, Murakami, Shin-ya, Peralta, Javier, Limaye, Sanjay S., Imamura, Takeshi, Nakamura, Masato, Sato, Takao M., Satoh, Takehiko, Horinouchi, Takeshi, Hayashi, Yoshi-Yuki, Watanabe, Shigeto, Yamada, Manabu, Yamazaki, Atsushi, Kouyama, Toru, Taguchi, Makoto, Fukuhara, Tetsuya, Takagi, Masahiro, Ogohara, Kazunori, Murakami, Shin-ya, Peralta, Javier, Limaye, Sanjay S., Imamura, Takeshi, Nakamura, Masato, Sato, Takao M., and Satoh, Takehiko

Abstract

Venus has a thick atmosphere that rotates 60 times as fast as the surface, a phenomenon known as superrotation. We use data obtained from the orbiting Akatsuki spacecraft to investigate how the super-rotation is maintained in the cloud layer, where the rotation speed is highest. A thermally induced latitudinal-vertical circulation acts to homogenize the distribution of the angular momentum around the rotational axis. Maintaining the super-rotation requires this to be counteracted by atmospheric waves and turbulence. Among those effects, thermal tides transport the angular momentum, which maintains the rotation peak, near the cloud top at low latitudes. Other planetary-scale waves and large-scale turbulence act in the opposite direction. We suggest that hydrodynamic instabilities adjust the angular-momentum distribution at mid-latitudes.

Published

2020

13. How waves and turbulence maintain the super-rotation of Venus' atmosphere

Author

1000050314266, Horinouchi, Takeshi, 1000020180979, Hayashi, Yoshi-Yuki, 1000090271577, Watanabe, Shigeto, 1000040451512, Yamada, Manabu, 1000000374893, Yamazaki, Atsushi, 1000040645876, Kouyama, Toru, 1000070236404, Taguchi, Makoto, 1000070435808, Fukuhara, Tetsuya, 1000000323494, Takagi, Masahiro, 1000050644853, Ogohara, Kazunori, Murakami, Shin-ya, Peralta, Javier, Limaye, Sanjay S., 1000040311170, Imamura, Takeshi, 1000020227937, Nakamura, Masato, Sato, Takao M., 1000010297632, Satoh, Takehiko, 1000050314266, Horinouchi, Takeshi, 1000020180979, Hayashi, Yoshi-Yuki, 1000090271577, Watanabe, Shigeto, 1000040451512, Yamada, Manabu, 1000000374893, Yamazaki, Atsushi, 1000040645876, Kouyama, Toru, 1000070236404, Taguchi, Makoto, 1000070435808, Fukuhara, Tetsuya, 1000000323494, Takagi, Masahiro, 1000050644853, Ogohara, Kazunori, Murakami, Shin-ya, Peralta, Javier, Limaye, Sanjay S., 1000040311170, Imamura, Takeshi, 1000020227937, Nakamura, Masato, Sato, Takao M., 1000010297632, and Satoh, Takehiko

Abstract

Venus has a thick atmosphere that rotates 60 times as fast as the surface, a phenomenon known as superrotation. We use data obtained from the orbiting Akatsuki spacecraft to investigate how the super-rotation is maintained in the cloud layer, where the rotation speed is highest. A thermally induced latitudinal-vertical circulation acts to homogenize the distribution of the angular momentum around the rotational axis. Maintaining the super-rotation requires this to be counteracted by atmospheric waves and turbulence. Among those effects, thermal tides transport the angular momentum, which maintains the rotation peak, near the cloud top at low latitudes. Other planetary-scale waves and large-scale turbulence act in the opposite direction. We suggest that hydrodynamic instabilities adjust the angular-momentum distribution at mid-latitudes.

Published

2020

14. How waves and turbulence maintain the super-rotation of Venus' atmosphere

Author

Horinouchi, Takeshi, Hayashi, Yoshi-Yuki, Watanabe, Shigeto, Yamada, Manabu, Yamazaki, Atsushi, Kouyama, Toru, Taguchi, Makoto, Fukuhara, Tetsuya, Takagi, Masahiro, Ogohara, Kazunori, Murakami, Shin-ya, Peralta, Javier, Limaye, Sanjay S., Imamura, Takeshi, Nakamura, Masato, Sato, Takao M., Satoh, Takehiko, Horinouchi, Takeshi, Hayashi, Yoshi-Yuki, Watanabe, Shigeto, Yamada, Manabu, Yamazaki, Atsushi, Kouyama, Toru, Taguchi, Makoto, Fukuhara, Tetsuya, Takagi, Masahiro, Ogohara, Kazunori, Murakami, Shin-ya, Peralta, Javier, Limaye, Sanjay S., Imamura, Takeshi, Nakamura, Masato, Sato, Takao M., and Satoh, Takehiko

Abstract

Venus has a thick atmosphere that rotates 60 times as fast as the surface, a phenomenon known as superrotation. We use data obtained from the orbiting Akatsuki spacecraft to investigate how the super-rotation is maintained in the cloud layer, where the rotation speed is highest. A thermally induced latitudinal-vertical circulation acts to homogenize the distribution of the angular momentum around the rotational axis. Maintaining the super-rotation requires this to be counteracted by atmospheric waves and turbulence. Among those effects, thermal tides transport the angular momentum, which maintains the rotation peak, near the cloud top at low latitudes. Other planetary-scale waves and large-scale turbulence act in the opposite direction. We suggest that hydrodynamic instabilities adjust the angular-momentum distribution at mid-latitudes.

Published

2020

15. Venus' Mass Spectra Show Signs of Disequilibria in the Middle Clouds

Author

Mogul, Rakesh, Limaye, Sanjay S., Way, M. J., Cordova Jr, Jamie A., Mogul, Rakesh, Limaye, Sanjay S., Way, M. J., and Cordova Jr, Jamie A.

Abstract

We present a re-examination of mass spectral data obtained from the Pioneer Venus Large Probe Neutral Mass Spectrometer. Our interpretations of differing trace chemical species are suggestive of redox disequilibria in Venus' middle clouds. Assignments to the data (at 51.3 km) include phosphine, hydrogen sulfide, nitrous acid, nitric acid, carbon monoxide, hydrochloric acid, hydrogen cyanide, ethane, and potentially ammonia, chlorous acid, and several tentative PxOy species. All parent ions were predicated upon assignment of corresponding fragmentation products, isotopologues, and atomic species. The data reveal parent ions at varying oxidation states, implying the presence of reducing power in the clouds, and illuminating the potential for chemistries yet to be discovered. When considering the hypothetical habitability of Venus' clouds, the assignments reveal a potential signature of anaerobic phosphorus metabolism (phosphine), an electron donor for anoxygenic photosynthesis (nitrite), and major constituents of the nitrogen cycle (nitrate, nitrite, ammonia, and N2)., Comment: <5000 words, 1 figure, 1 table, several supplemental items

Published

2020

16. Nightside Winds at the Lower Clouds of Venus with Akatsuki/IR2: Longitudinal, local time and decadal variations from comparison with previous measurements

Author

Peralta, Javier, Muto, Keishiro, Hueso, Ricardo, Horinouchi, Takeshi, Sánchez-Lavega, Agustín, Murakami, Shin-ya, Machado, Pedro, Young, Eliot F., Lee, Yeon Joo, Kouyama, Toru, Sagawa, Hideo, McGouldrick, Kevin, Satoh, Takehiko, Imamura, Takeshi, Limaye, Sanjay S., Sato, Takao M., Ogohara, Kazunori, Nakamura, Masato, Luz, David, Peralta, Javier, Muto, Keishiro, Hueso, Ricardo, Horinouchi, Takeshi, Sánchez-Lavega, Agustín, Murakami, Shin-ya, Machado, Pedro, Young, Eliot F., Lee, Yeon Joo, Kouyama, Toru, Sagawa, Hideo, McGouldrick, Kevin, Satoh, Takehiko, Imamura, Takeshi, Limaye, Sanjay S., Sato, Takao M., Ogohara, Kazunori, Nakamura, Masato, and Luz, David

Abstract

We present measurements of the wind speeds at the nightside lower clouds of Venus from observations by JAXA's mission Akatsuki during 2016, complemented with new wind measurements from ground-based observations acquired with TNG/NICS in 2012 and IRTF/SpeX in 2015 and 2017. Zonal and meridional components of the winds were measured from cloud tracking on a total of 466 Akatsuki images of Venus acquired by the camera IR2 using the 2.26-$\mathrm{\mu m}$ filter, with spatial resolutions ranging 10--80 km per pixel and covering from 2016 March 22 to October 31. More than 149,000 wind vectors were obtained with an automatic technique of template matching, and 2,947 wind vectors were inferred with the manual procedure. The meridional profiles for both components of the winds are found to be consistent with results from the Venus Express mission during 2006--2008, although stronger wind variability is found for the zonal component at equatorial latitudes where Akatsuki observations have better viewing geometry than Venus Express. The zonal winds at low latitudes also suggest a zonal variability that could be associated with solar tides or vertically propagating orographic waves. Finally, the combination of our wind measurements from TNG/NICS, IRTF/SpeX and Akatsuki images with previously published and based in data from 1978 to 2017 suggests variations of up to 30 m s$^{-1}$ in the winds at the lower clouds of the Venus nightside., Comment: 20 pages, 13 figures, Supplemental Material available at ApJS

Published

2018

17. Adiabatic Lapse Rate and Static Stability in the Venus Atmosphere calculated from Real Gas Mixture Models

Author

Dutt, Arkopal, Limaye, Sanjay S., Dutt, Arkopal, and Limaye, Sanjay S.

Abstract

It is known that the ideal gas equation of state is not valid in the lower atmosphere of Venus where surface pressures reach 9 MPa and surface temperatures approach 750K. Moreover, the presence of a small amount of nitrogen slightly complicates the calculation of thermodynamic properties of the real gas mixture present in the atmosphere. Previous calculations of the adiabatic lapse rate in the Venus atmosphere have used approximations to estimate the adiabatic lapse rate. Here, we calculate the adiabatic lapse rate more accurately by using multi-parameter mixture models formulated in reduced Helmholtz free energy to account for the real gas mixture effects. Our results show small differences from the Seiff et al. (1980) values for the adiabatic lapse rate which may be significant where the Venus atmosphere is close to being neutral. For accurate knowledge of the static stability for atmosphere circulation, a local value of the adiabatic lapse rate is necessary.

Published

2018

18. Venus looks different from day to night across wavelengths: morphology from Akatsuki multispectral images

Author

Limaye, Sanjay S., Watanabe, Shigeto, Yamazaki, Atsushi, Yamada, Manabu, Satoh, Takehiko, Sato, Takao M., Nakamura, Masato, Taguchi, Makoto, Fukuhara, Tetsuya, Imamura, Takeshi, Kouyama, Toru, Lee, Yeon Joo, Horinouchi, Takeshi, Peralta, Javier, Iwagami, Naomoto, Hashimoto, George L., Takagi, Seiko, Ohtsuki, Shoko, Murakami, Shin-ya, Yamamoto, Yukio, Ogohara, Kazunori, Ando, Hiroki, Sugiyama, Ko-ichiro, Ishii, Nobuaki, Abe, Takumi, Hirose, Chikako, Suzuki, Makoto, Hirata, Naru, Young, Eliot F., Ocampo, Adriana C., 渡部, 重十, 山崎, 敦, 山田, 学, 佐藤, 毅彦, 佐藤, 隆雄, 中村, 正人, 田口, 真, 福原, 哲哉, 今村, 剛, 神山, 徹, 堀之内, 武, 岩上, 直幹, はしもと, じょーじ, 高木, 聖子, 大月, 祥子, 村上, 真也, 山本, 幸生, 小郷原, 一智, 安藤, 紘基, 杉山, 耕一朗, 石井, 信明, 阿部, 琢美, 廣瀬, 史子, 鈴木, 睦, 平田, 成, Limaye, Sanjay S., Watanabe, Shigeto, Yamazaki, Atsushi, Yamada, Manabu, Satoh, Takehiko, Sato, Takao M., Nakamura, Masato, Taguchi, Makoto, Fukuhara, Tetsuya, Imamura, Takeshi, Kouyama, Toru, Lee, Yeon Joo, Horinouchi, Takeshi, Peralta, Javier, Iwagami, Naomoto, Hashimoto, George L., Takagi, Seiko, Ohtsuki, Shoko, Murakami, Shin-ya, Yamamoto, Yukio, Ogohara, Kazunori, Ando, Hiroki, Sugiyama, Ko-ichiro, Ishii, Nobuaki, Abe, Takumi, Hirose, Chikako, Suzuki, Makoto, Hirata, Naru, Young, Eliot F., Ocampo, Adriana C., 渡部, 重十, 山崎, 敦, 山田, 学, 佐藤, 毅彦, 佐藤, 隆雄, 中村, 正人, 田口, 真, 福原, 哲哉, 今村, 剛, 神山, 徹, 堀之内, 武, 岩上, 直幹, はしもと, じょーじ, 高木, 聖子, 大月, 祥子, 村上, 真也, 山本, 幸生, 小郷原, 一智, 安藤, 紘基, 杉山, 耕一朗, 石井, 信明, 阿部, 琢美, 廣瀬, 史子, 鈴木, 睦, and 平田, 成

Abstract

著者人数: 30名, Accepted: 2018-01-24

Published

2018

19. Venus Atmospheric Thermal Structure and Radiative Balance

Author

Limaye, Sanjay S., Grassi, Davide, Mahieux, Arnaud, Migliorini, Alessandra, Tellmann, Silvia, Titov, Dmitrij, Limaye, Sanjay S., Grassi, Davide, Mahieux, Arnaud, Migliorini, Alessandra, Tellmann, Silvia, and Titov, Dmitrij

Abstract

From the discovery that Venus has an atmosphere during the 1761 transit by M. Lomonosov to the current exploration of the planet by the Akatsuki orbiter, we continue to learn about the planet's extreme climate and weather. This chapter attempts to provide a comprehensive but by no means exhaustive review of the results of the atmospheric thermal structure and radiative balance since the earlier works published in Venus and Venus II books from recent spacecraft and Earth based investigations and summarizes the gaps in our current knowledge. There have been no in-situ measurements of the deep Venus atmosphere since the flights of the two VeGa balloons and landers in 1985 (Sagdeev et al., Science 231:1411-1414, 1986). Thus, most of the new information about the atmospheric thermal structure has come from different remote sensing (Earth based and spacecraft) techniques using occultations (solar infrared, stellar ultraviolet and orbiter radio occultations), spectroscopy and microwave, short wave and thermal infrared emissions. The results are restricted to altitudes higher than about 40 km, except for one investigation of the near surface static stability inferred by Meadows and Crisp (J. Geophys. Res. 101:4595-4622, 1996) from 1 m observations from Earth. Little information about the lower atmospheric structure is possible below about 40 km altitude from radio occultations due to large bending angles. The gaps in our knowledge include spectral albedo variations over time, vertical variation of the bulk composition of the atmosphere (mean molecular weight), the identity, properties and abundances of absorbers of incident solar radiation in the clouds. The causes of opacity variations in the nightside cloud cover and vertical gradients in the deep atmosphere bulk composition and its impact on static stability are also in need of critical studies. The knowledge gaps and questions about Venus and its atmosphere provide the incentive for obtaining the necessary measurements

Published

2018

20. Venus Atmospheric Thermal Structure and Radiative Balance

Author

Limaye, Sanjay S., Grassi, Davide, Mahieux, Arnaud, Migliorini, Alessandra, Tellmann, Silvia, Titov, Dmitrij, Limaye, Sanjay S., Grassi, Davide, Mahieux, Arnaud, Migliorini, Alessandra, Tellmann, Silvia, and Titov, Dmitrij

Abstract

From the discovery that Venus has an atmosphere during the 1761 transit by M. Lomonosov to the current exploration of the planet by the Akatsuki orbiter, we continue to learn about the planet's extreme climate and weather. This chapter attempts to provide a comprehensive but by no means exhaustive review of the results of the atmospheric thermal structure and radiative balance since the earlier works published in Venus and Venus II books from recent spacecraft and Earth based investigations and summarizes the gaps in our current knowledge. There have been no in-situ measurements of the deep Venus atmosphere since the flights of the two VeGa balloons and landers in 1985 (Sagdeev et al., Science 231:1411-1414, 1986). Thus, most of the new information about the atmospheric thermal structure has come from different remote sensing (Earth based and spacecraft) techniques using occultations (solar infrared, stellar ultraviolet and orbiter radio occultations), spectroscopy and microwave, short wave and thermal infrared emissions. The results are restricted to altitudes higher than about 40 km, except for one investigation of the near surface static stability inferred by Meadows and Crisp (J. Geophys. Res. 101:4595-4622, 1996) from 1 m observations from Earth. Little information about the lower atmospheric structure is possible below about 40 km altitude from radio occultations due to large bending angles. The gaps in our knowledge include spectral albedo variations over time, vertical variation of the bulk composition of the atmosphere (mean molecular weight), the identity, properties and abundances of absorbers of incident solar radiation in the clouds. The causes of opacity variations in the nightside cloud cover and vertical gradients in the deep atmosphere bulk composition and its impact on static stability are also in need of critical studies. The knowledge gaps and questions about Venus and its atmosphere provide the incentive for obtaining the necessary measurements

Published

2018

21. Nightside Winds at the Lower Clouds of Venus with Akatsuki/IR2: Longitudinal, local time and decadal variations from comparison with previous measurements

Author

Peralta, Javier, Muto, Keishiro, Hueso, Ricardo, Horinouchi, Takeshi, Sánchez-Lavega, Agustín, Murakami, Shin-ya, Machado, Pedro, Young, Eliot F., Lee, Yeon Joo, Kouyama, Toru, Sagawa, Hideo, McGouldrick, Kevin, Satoh, Takehiko, Imamura, Takeshi, Limaye, Sanjay S., Sato, Takao M., Ogohara, Kazunori, Nakamura, Masato, Luz, David, Peralta, Javier, Muto, Keishiro, Hueso, Ricardo, Horinouchi, Takeshi, Sánchez-Lavega, Agustín, Murakami, Shin-ya, Machado, Pedro, Young, Eliot F., Lee, Yeon Joo, Kouyama, Toru, Sagawa, Hideo, McGouldrick, Kevin, Satoh, Takehiko, Imamura, Takeshi, Limaye, Sanjay S., Sato, Takao M., Ogohara, Kazunori, Nakamura, Masato, and Luz, David

Abstract

We present measurements of the wind speeds at the nightside lower clouds of Venus from observations by JAXA's mission Akatsuki during 2016, complemented with new wind measurements from ground-based observations acquired with TNG/NICS in 2012 and IRTF/SpeX in 2015 and 2017. Zonal and meridional components of the winds were measured from cloud tracking on a total of 466 Akatsuki images of Venus acquired by the camera IR2 using the 2.26-$\mathrm{\mu m}$ filter, with spatial resolutions ranging 10--80 km per pixel and covering from 2016 March 22 to October 31. More than 149,000 wind vectors were obtained with an automatic technique of template matching, and 2,947 wind vectors were inferred with the manual procedure. The meridional profiles for both components of the winds are found to be consistent with results from the Venus Express mission during 2006--2008, although stronger wind variability is found for the zonal component at equatorial latitudes where Akatsuki observations have better viewing geometry than Venus Express. The zonal winds at low latitudes also suggest a zonal variability that could be associated with solar tides or vertically propagating orographic waves. Finally, the combination of our wind measurements from TNG/NICS, IRTF/SpeX and Akatsuki images with previously published and based in data from 1978 to 2017 suggests variations of up to 30 m s$^{-1}$ in the winds at the lower clouds of the Venus nightside., Comment: 20 pages, 13 figures, Supplemental Material available at ApJS

Published

2018

22. Adiabatic Lapse Rate and Static Stability in the Venus Atmosphere calculated from Real Gas Mixture Models

Author

Dutt, Arkopal, Limaye, Sanjay S., Dutt, Arkopal, and Limaye, Sanjay S.

Abstract

It is known that the ideal gas equation of state is not valid in the lower atmosphere of Venus where surface pressures reach 9 MPa and surface temperatures approach 750K. Moreover, the presence of a small amount of nitrogen slightly complicates the calculation of thermodynamic properties of the real gas mixture present in the atmosphere. Previous calculations of the adiabatic lapse rate in the Venus atmosphere have used approximations to estimate the adiabatic lapse rate. Here, we calculate the adiabatic lapse rate more accurately by using multi-parameter mixture models formulated in reduced Helmholtz free energy to account for the real gas mixture effects. Our results show small differences from the Seiff et al. (1980) values for the adiabatic lapse rate which may be significant where the Venus atmosphere is close to being neutral. For accurate knowledge of the static stability for atmosphere circulation, a local value of the adiabatic lapse rate is necessary.

Published

2018

23. The thermal structure of the Venus atmosphere: Intercomparison of Venus Express and ground based observations of vertical temperature and density profiles

Author

Limaye, Sanjay S., Lebonnois, Sebastien, Mahieux, Arnaud, Paetzold, Martin, Bougher, Steven, Bruinsma, Sean, Chamberlain, Sarah, Clancy, R. Todd, Gerard, Jean-Claude, Gilli, Gabriella, Grassi, Davide, Haus, Rainer, Herrmann, Maren, Imamura, Takeshi, Kohler, Erika, Krause, Pia, Migliorini, Alessandra, Montmessin, Franck, Pere, Christophe, Persson, Moa, Piccialli, Arianna, Rengel, Miriam, Rodin, Alexander, Sandor, Brad, Sornig, Manuela, Svedhem, Hakan, Tellmann, Silvia, Tanga, Paolo, Vandaele, Ann C., Widemann, Thomas, Wilson, Colin F., Mueller-Wodarg, Ingo, Zasova, Ludmila, 今村, 剛, Limaye, Sanjay S., Lebonnois, Sebastien, Mahieux, Arnaud, Paetzold, Martin, Bougher, Steven, Bruinsma, Sean, Chamberlain, Sarah, Clancy, R. Todd, Gerard, Jean-Claude, Gilli, Gabriella, Grassi, Davide, Haus, Rainer, Herrmann, Maren, Imamura, Takeshi, Kohler, Erika, Krause, Pia, Migliorini, Alessandra, Montmessin, Franck, Pere, Christophe, Persson, Moa, Piccialli, Arianna, Rengel, Miriam, Rodin, Alexander, Sandor, Brad, Sornig, Manuela, Svedhem, Hakan, Tellmann, Silvia, Tanga, Paolo, Vandaele, Ann C., Widemann, Thomas, Wilson, Colin F., Mueller-Wodarg, Ingo, Zasova, Ludmila, and 今村, 剛

Abstract

著者人数: 33名, Accepted: 2017-04-19

Published

2017

24. The thermal structure of the Venus atmosphere: Intercomparison of Venus Express and ground based observations of vertical temperature and density profiles

Author

Limaye, Sanjay S., Lebonnois, Sebastien, Mahieux, Arnaud, Paetzold, Martin, Bougher, Steven, Bruinsma, Sean, Chamberlain, Sarah, Clancy, R. Todd, Gerard, Jean-Claude, Gilli, Gabriella, Grassi, Davide, Haus, Rainer, Herrmann, Maren, Imamura, Takeshi, Kohler, Erika, Krause, Pia, Migliorini, Alessandra, Montmessin, Franck, Pere, Christophe, Persson, Moa, Piccialli, Arianna, Rengel, Miriam, Rodin, Alexander, Sandor, Brad, Sornig, Manuela, Svedhem, Hakan, Tellmann, Silvia, Tanga, Paolo, Vandaele, Ann C., Widemann, Thomas, Wilson, Colin F., Mueller-Wodarg, Ingo, Zasova, Ludmila, Limaye, Sanjay S., Lebonnois, Sebastien, Mahieux, Arnaud, Paetzold, Martin, Bougher, Steven, Bruinsma, Sean, Chamberlain, Sarah, Clancy, R. Todd, Gerard, Jean-Claude, Gilli, Gabriella, Grassi, Davide, Haus, Rainer, Herrmann, Maren, Imamura, Takeshi, Kohler, Erika, Krause, Pia, Migliorini, Alessandra, Montmessin, Franck, Pere, Christophe, Persson, Moa, Piccialli, Arianna, Rengel, Miriam, Rodin, Alexander, Sandor, Brad, Sornig, Manuela, Svedhem, Hakan, Tellmann, Silvia, Tanga, Paolo, Vandaele, Ann C., Widemann, Thomas, Wilson, Colin F., Mueller-Wodarg, Ingo, and Zasova, Ludmila

Abstract

The Venus International Reference Atmosphere (VIRA) model contains tabulated values of temperature and number densities obtained by the experiments on the Venera entry probes, Pioneer Venus Orbiter and multi-probe missions in the 1980s. The instruments on the recent Venus Express orbiter mission generated a significant amount of new observational data on the vertical and horizontal structure of the Venus atmosphere from 40 km to about 180 km altitude from April 2006 to November 2014. Many ground based experiments have provided data on the upper atmosphere (90-130 km) temperature structure since the publication of VIRA in 1985. The Thermal Structure of the Venus Atmosphere Team was supported by the International Space Studies Institute (ISSI), Bern, Switzerland, from 2013 to 2015 in order to combine and compare the ground-based observations and the VEx observations of the thermal structure as a first step towards generating an updated VIRA model. Results of this comparison are presented in five latitude bins and three local time bins by assuming hemispheric symmetry. The inter comparison of the ground-based and VEx results provides for the first time a consistent picture of the temperature and density structure in the 40 km-180 km altitude range. The Venus Express observations have considerably increased our knowledge of the Venus atmospheric thermal structure above 40 km and provided new information above 100 km. There are, however, still observational gaps in latitude and local time above certain regions. Considerable variability in the temperatures and densities is seen above 100 km but certain features appear to be systematically present, such as a succession of warm and cool layers. Preliminary modeling studies support the existence of such layers in agreement with a global scale circulation. The intercomparison focuses on average profiles but some VEx experiments provide sufficient global coverage to identify solar thermal tidal components. The differences betw

Published

2017

25. The thermal structure of the Venus atmosphere: Intercomparison of Venus Express and ground based observations of vertical temperature and density profiles

Author

Limaye, Sanjay S., Lebonnois, Sebastien, Mahieux, Arnaud, Paetzold, Martin, Bougher, Steven, Bruinsma, Sean, Chamberlain, Sarah, Clancy, R. Todd, Gerard, Jean-Claude, Gilli, Gabriella, Grassi, Davide, Haus, Rainer, Herrmann, Maren, Imamura, Takeshi, Kohler, Erika, Krause, Pia, Migliorini, Alessandra, Montmessin, Franck, Pere, Christophe, Persson, Moa, Piccialli, Arianna, Rengel, Miriam, Rodin, Alexander, Sandor, Brad, Sornig, Manuela, Svedhem, Hakan, Tellmann, Silvia, Tanga, Paolo, Vandaele, Ann C., Widemann, Thomas, Wilson, Colin F., Mueller-Wodarg, Ingo, Zasova, Ludmila, Limaye, Sanjay S., Lebonnois, Sebastien, Mahieux, Arnaud, Paetzold, Martin, Bougher, Steven, Bruinsma, Sean, Chamberlain, Sarah, Clancy, R. Todd, Gerard, Jean-Claude, Gilli, Gabriella, Grassi, Davide, Haus, Rainer, Herrmann, Maren, Imamura, Takeshi, Kohler, Erika, Krause, Pia, Migliorini, Alessandra, Montmessin, Franck, Pere, Christophe, Persson, Moa, Piccialli, Arianna, Rengel, Miriam, Rodin, Alexander, Sandor, Brad, Sornig, Manuela, Svedhem, Hakan, Tellmann, Silvia, Tanga, Paolo, Vandaele, Ann C., Widemann, Thomas, Wilson, Colin F., Mueller-Wodarg, Ingo, and Zasova, Ludmila

Abstract

The Venus International Reference Atmosphere (VIRA) model contains tabulated values of temperature and number densities obtained by the experiments on the Venera entry probes, Pioneer Venus Orbiter and multi-probe missions in the 1980s. The instruments on the recent Venus Express orbiter mission generated a significant amount of new observational data on the vertical and horizontal structure of the Venus atmosphere from 40 km to about 180 km altitude from April 2006 to November 2014. Many ground based experiments have provided data on the upper atmosphere (90-130 km) temperature structure since the publication of VIRA in 1985. The Thermal Structure of the Venus Atmosphere Team was supported by the International Space Studies Institute (ISSI), Bern, Switzerland, from 2013 to 2015 in order to combine and compare the ground-based observations and the VEx observations of the thermal structure as a first step towards generating an updated VIRA model. Results of this comparison are presented in five latitude bins and three local time bins by assuming hemispheric symmetry. The inter comparison of the ground-based and VEx results provides for the first time a consistent picture of the temperature and density structure in the 40 km-180 km altitude range. The Venus Express observations have considerably increased our knowledge of the Venus atmospheric thermal structure above 40 km and provided new information above 100 km. There are, however, still observational gaps in latitude and local time above certain regions. Considerable variability in the temperatures and densities is seen above 100 km but certain features appear to be systematically present, such as a succession of warm and cool layers. Preliminary modeling studies support the existence of such layers in agreement with a global scale circulation. The intercomparison focuses on average profiles but some VEx experiments provide sufficient global coverage to identify solar thermal tidal components. The differences betw

Published

2017

26. Rational Approximation Formula for Chandrasekhar's H-function for Isotropic Scattering

Author

Kawabata, Kiyoshi, Limaye, Sanjay S., Kawabata, Kiyoshi, and Limaye, Sanjay S.

Abstract

We first establish a simple procedure to obtain with 11-figure accuracy the values of Chandrasekhar's H-function for isotropic scattering using a closed-form integral representation and the Gauss-Legendre quadrature. Based on the numerical values of the function produced by this method for various values of the single scattering albedo and the cosine of the azimuth angle of the direction of radiation emergent from or incident upon a semi-infinite scattering-absorbing medium, we propose a rational approximation formula, which allows us to reproduce the correct values of the H-function within a relative error of 2.1/100000 without recourse to any iterative procedure or root-finding process., Comment: 12 pages, 1 table, Accepted for publication in Astrophysics and Space Science

Published

2010

27. Rational Approximation Formula for Chandrasekhar's H-function for Isotropic Scattering

Author

Kawabata, Kiyoshi, Limaye, Sanjay S., Kawabata, Kiyoshi, and Limaye, Sanjay S.

Abstract

We first establish a simple procedure to obtain with 11-figure accuracy the values of Chandrasekhar's H-function for isotropic scattering using a closed-form integral representation and the Gauss-Legendre quadrature. Based on the numerical values of the function produced by this method for various values of the single scattering albedo and the cosine of the azimuth angle of the direction of radiation emergent from or incident upon a semi-infinite scattering-absorbing medium, we propose a rational approximation formula, which allows us to reproduce the correct values of the H-function within a relative error of 2.1/100000 without recourse to any iterative procedure or root-finding process., Comment: 12 pages, 1 table, Accepted for publication in Astrophysics and Space Science

Published

2010

28. Imaging the surface of Mercury using ground-based telescopes

Author

Mendillo, Michael, Warell, Johan, Limaye, Sanjay S., Baumgardner, Jeffrey, Sprague, Ann, Wilson, Jody K., Mendillo, Michael, Warell, Johan, Limaye, Sanjay S., Baumgardner, Jeffrey, Sprague, Ann, and Wilson, Jody K.

Abstract

We describe and compare two methods of short-exposure, high-definition ground-based imaging of the planet Mercury. Two teams haverecorded images of Mercury on different dates, from different locations, and with different observational and data reduction

Published

2001

29. Dynamic Meteorology of Neptune

Author

Cruikshank, Dale P., Matthews, Mildred Shapley, Schumann, A. M., Ingersoll, Andrew P., Barnet, Christopher D., Beebe, Reta F., Flasar, F. Michael, Hinson, David P., Limaye, Sanjay S., Sromovsky, Lawrence A., Suomi, Verner E., Cruikshank, Dale P., Matthews, Mildred Shapley, Schumann, A. M., Ingersoll, Andrew P., Barnet, Christopher D., Beebe, Reta F., Flasar, F. Michael, Hinson, David P., Limaye, Sanjay S., Sromovsky, Lawrence A., and Suomi, Verner E.

Abstract

Although Earth-based observations provide hints of Neptune's dynamic activity, most of the observations of cloud patterns, winds, and horizontal variations in temperature are from Voyager. The wind speed varies from 400 m s^(-1) westward at the equator to 250m s^(-1) eastward at -70° latitude. As on all the giant planets, the winds decay with height in the stratosphere. The meridional contrasts in temperature are small in the upper troposphere and lower stratosphere, with mid-latitude minima that are reminiscent of those on Uranus. The oscillations and motions of Neptune's large spots are more regular than those of Jupiter and Saturn. During the Voyager observations, the Great Dark Spot moved steadily equatorward while it oscillated in shape with an 8-day period. The latitude and longitude of Dark Spot 2 oscillated with a 36-day period. The small elements within each major feature appeared and disappeared in less than a day. Such activity is remarkable for a planet whose emitted power per unit area is 1/20 that of Jupiter and 1/400 that of the Earth. Weak viscosity can account for the decay of winds in the stratosphere, and models without viscosity can account for the spot oscillations. But the wind velocities and temperatures vs latitude--especially the differences among the giant planets--have not been explained. Major unknowns concern convection and latent heat release, the interaction with Neptune's fluid interior, and the importance of internal energy relative to solar energy in driving the circulation.

Published

1995