Your search keyword '"Kolokolova, Ludmilla"' showing total 10 results

1. Planetary science: Cometary dust under the microscope.

Author

Kolokolova L

Subjects

Extraterrestrial Environment, Meteoroids, Dust, Planets

Published

2016

2. Photopolarimetric remote sensing of aggregates in cosmic dust

Author

Kolokolova, Ludmilla, Mishchenko, Michael I., editor, Yatskiv, Yaroslav S., editor, Rosenbush, Vera K., editor, and Videen, Gorden, editor

Published

2011

3. Comet dust as a mixture of aggregates and solid particles: Model consistent with ground-based and space-mission results

Author

Kolokolova, Ludmilla and Kimura, Hiroshi

Published

2010

4. Photometry, spectroscopy, and polarimetry of distant comet C/2014 A4 (SONEAR).

Author

Ivanova, Oleksandra, Luk'yanyk, Igor, Kolokolova, Ludmilla, Das, Himadri Sekhar, Husárik, Marek, Rosenbush, Vera, Afanasiev, Viktor, Svoreň, Ján, Kiselev, Nikolai, and Krushinsky, Vadim

Subjects

PHOTOMETRY, DUST, POLARIMETRY, SPECTRUM analysis, COMETS, SPATIAL variation

Abstract

Context. The study of distant comets, which are active at large heliocentric distances, is important for a better understanding of their physical properties and mechanisms of long-lasting activity. Aims. We analyzed the dust environment of the distant comet C/2014 A4 (SONEAR), with a perihelion distance near 4.1 au, using comprehensive observations obtained by different methods. Methods. We present an analysis of spectroscopy, photometry, and polarimetry of comet C/2014 A4 (SONEAR), which were performed on November 5–7, 2015, when its heliocentric distance was 4.2 au and phase angle was 4.7°. Long-slit spectra and photometric and linear polarimetric images were obtained using the focal reducer SCORPIO-2 attached to the prime focus of the 6 m telescope BTA (SAO RAS, Russia). We simulated the behavior of color and polarization in the coma presenting the cometary dust as a set of polydisperse polyshapes rough spheroids. Results. No emission features were detected in the 3800–7200 Å wavelength range. The continuum showed a reddening effect with the normalized gradient of reflectivity 21.6 ± 0.2% per 1000 Å within the 4650–6200 Å wavelength region. The fan-like structure in the sunward hemisphere was detected. The radial profiles of surface brightness differ for r-sdss and g-sdss filters, indicating a predominance of submicron and micron-sized particles in the cometary coma. The dust color (g–r) varies from 0.75 ± 0.05m to 0.45 ± 0.06m along the tail. For an aperture radius near 20 000 km, the dust productions in various filters were estimated as Afρ = 680 ± 18 cm (r-sdss) and 887 ± 16 cm (g-sdss). The polarization map shows spatial variations in polarization over the coma from about −3% near the nucleus to −8% at a cometocentric distance of about 150 000 km. Our simulations show that the dust particles are dominated (or covered) by ice and tholin-like organics. Spatial changes in the color and polarization can be explained by particle fragmentation. [ABSTRACT FROM AUTHOR]

Published

2019

5. Light scattering by hierarchical aggregates.

Author

Kolokolova, Ludmilla, Nagdimunov, Lev, and Mackowski, Daniel

Subjects

*LIGHT scattering, *CHURYUMOV-Gerasimenko comet, *DUST, *COMPUTER simulation, *PHOTOMETRY

Abstract

Recent in-situ studies of the environment of comet 67P/Churyumov–Gerasimenko by the dust instruments onboard the Rosetta spacecraft have indicated a complex structure of cometary dust particles. The majority of those particles appeared to be large aggregates of hierarchical structure, i.e. aggregates of particles, which, in turn, were aggregates of smaller particles. This confirmed an earlier hypothesis that dust particles in protoplanetary disks grow under hierarchical growth process. Thus, it is very likely that hierarchical aggregates are common type of natural dust particles. In this paper, we present results of computer simulations of light scattering by a variety of hierarchical aggregates to determine how their structure affects their brightness and polarization phase curves as well as photometric and polarimetric color, and albedo. The computations were done using Multi-Sphere T-Matrix method. Our results show that the type of hierarchical structure of aggregates, specified by the number of particles at each level of hierarchy, causes variations in their light-scattering characteristics, which noticeably exceed the variations caused by different configuration of monomers in the aggregates of the same hierarchical structure. Although we could not find any regularities in the brightness and polarization dependence on the structure of the aggregates, our results clearly show that not only composition or size of aggregates, but also their specific structure should be carefully examined when light scattering by cometary or any other type of dust is modeled. Specifically, we may need to reconsider modeling the cometary dust particles using simple ballistic particle-cluster and cluster-cluster aggregates. [ABSTRACT FROM AUTHOR]

Published

2018

6. Properties of comet 9P/Tempel 1 dust immediately following excavation by deep impact.

Author

Nagdimunov, Lev, Kolokolova, Ludmilla, Wolff, Michael, A'Hearn, Michael F., and Farnham, Tony L.

Subjects

*TEMPEL 1 comet, *EXCAVATION, *HIGH resolution imaging, *LIGHT scattering, *PARTICLE size distribution

Abstract

We analyzed Deep Impact High Resolution Instrument (HRI) images acquired within the first seconds after collision of the Deep Impact impactor with the nucleus of comet 9 P/Tempel 1. These images reveal an optically thick ejecta plume that casts a shadow on the surface of the nucleus. Using the 3D radiative transfer code HYPERION we simulated light scattering by the ejecta plume, taking into account multiple scattering of light from the ejecta, the surrounding nuclear surface and the actual observational geometry (including an updated plume orientation geometry that accounts for the latest 9 P/Tempel 1 shape model). Our primary dust model parameters were the number density of particles, their size distribution and composition. We defined the composition through the density of an individual particle and the ratio of its material constituents, which we considered to be refractories, ice and voids. The results of our modeling indicate a dust/ice mass ratio for the ejecta particles of at least 1. To further constrain the parameters of the model, we checked for consistency between the ejecta mass resulting from our modeling with the ejecta mass estimated by the crater formation modeling. Constraining the particle size distribution by results of other studies of the Deep Impact ejecta, we find the number density of ejecta particles equal to ∼104 particles/cm3 at the base of the plume. [ABSTRACT FROM AUTHOR]

Published

2014

7. Cosmic Dust VI.

Author

Kimura, Hiroshi, Kolokolova, Ludmilla, Li, Aigen, Inoue, Akio K., and Jäger, Cornelia

Subjects

*COSMIC dust, *PROTOPLANETARY disks, *CIRCUMSTELLAR matter, *INTERPLANETARY medium, *INTERSTELLAR reddening

Abstract

This special issue is primarily devoted to the 6th meeting on Cosmic Dust (Cosmic Dust VI), which was held at CPS (Center for Planetary Science) in Kobe, Japan, on August 5-9, 2013. This meeting was coordinated in an order where a friendly and welcoming atmosphere persuaded the participants of the meeting to develop human relations and interactions among themselves. This has been our interdisciplinary approach to answering the question of where dust comes from and where dust goes. We briefly review some of the exciting papers presented at the meeting and provide perspectives for the development of cosmic dust research. [ABSTRACT FROM AUTHOR]

Published

2014

8. Do twin spectral peaks of olivine particles in the thermal infrared diagnose their sizes and porosities?

Author

Kimura, Hiroshi, Markkanen, Johannes, Kolokolova, Ludmilla, Hilchenbach, Martin, Wada, Koji, Kanada, Yasumasa, and Matsui, Takafumi

Subjects

*OLIVINE, *DUST, *INFRARED spectra, *LIGHT scattering, *LIGHT absorption

Abstract

A well-established constraint on the size of non-porous olivine grains or the porosity of aggregates consisting of small olivine grains from prominent narrow peaks in thermal infrared spectra characteristic of crystalline silicates is reexamined. To thoroughly investigate thermal infrared peaks, we make theoretical argument for the absorption and scattering of light by non-porous, non-spherical olivine particles, which is followed by numerical verification. Our study provides perfectly rational explanations of the physics behind the small-particle effect of emission peaks in the framework of classical electrodynamics and convincing evidence of small-particle's emission peaks in the literature. While resonant absorption excited by surface roughness on the order of submicrometer scales can be identified even for non-porous olivine particles with a radius of 10 μ m, it makes only a negligible contribution to thermal infrared spectra of the particles. In contrast, the porosity of non-spherical particles has a significant impact on the strength and wavelength of the peaks, while the resonant absorption excited by an ensemble of small grains takes place at a wavelength different than one expects for surface roughness. We finally reaffirm that twin peaks of olivine in thermal infrared spectra of dust particles in astronomical environments are the intrinsic diagnostic characters of submicrometer-sized small grains and their aggregate particles in fluffy and porous configurations. • Twin peaks of olivine particles in the infrared spectra are revisited in the framework of classical electrodynamics. • Resonant absorption excited by submicrometer-sized surface roughness is negligible to the infrared peaks. • The porosity of non-spherical particles has a significant impact on the strength and wavelength of the peaks. • Twin spectral peaks of olivine particles in the thermal infrared diagnose the sizes and porosities of the particles. [ABSTRACT FROM AUTHOR]

Published

2022

9. Erratum to “A distribution of large particles in the coma of Comet 103P/Hartley 2” [Icarus 222 (2013) 634–652].

Author

Kelley, Michael S.P., Lindler, Don J., Bodewits, Dennis, A’Hearn, Michael F., Lisse, Carey M., Kolokolova, Ludmilla, Kissel, Jochen, and Hermalyn, Brendan

Subjects

*PUBLISHED errata, *PARTICLE size distribution, *COMETS, *ICE, *DUST, *PUBLISHED articles, *PUBLISHING

Published

2015

10. Comet 2P/Encke in apparition of 2017: II. Polarization and color.

Author

Kiselev, Nikolai, Rosenbush, Vera, Ivanova, Oleksandra, Kolokolova, Ludmilla, Petrov, Dmitry, Kleshchonok, Valeriy, Afanasiev, Viktor, and Shubina, Olena

Subjects

*GAUSSIAN beams, *COMETS, *DUST, *SCATTERING (Physics), *POLARIMETRY, *LIGHT scattering, *COLORS

Abstract

We present results of imaging polarimetry of comet 2P/Encke performed on January 23, 2017 at the heliocentric (1.052 au) and geocentric (1.336 au) distances and phase angle 46.8°, 46 days before perihelion. Observations were made through the medium-band SED500 (λ5019/246 Å) and broadband r-sdss (λ6200/1200 Å) filters with the multimode focal reducer SCORPIO-2 at the 6-m BTA telescope of the Special Astrophysical Observatory (Russia). Dust in comet 2P/Encke was mainly concentrated in the near-nucleus region of the coma: the maximum dust/gas to leave F em / F con t ratios were 1.5 and 2.9 in the SED500 and the r-sdss filters near the nucleus but dropped sharply to ~0.2 and ~1 at the distance ~2.500 km, respectively. Then these ratios began to increase at distances ~12,000 km from the nucleus, the ratio was ~0.3 (SED500) and ~ 1.3 (r-sdds). There were significant variations of polarization over the coma, which correlated with the variations in the dust color and dust/gas ratio. The maximum degree of polarization, ~8% in the r-sdss filter, was observed in the dust shell which was shifted by ~1.000 km towards the Sun. Polarization sharply dropped to ~4% at the distance ~3.000 km and then gradually increased with wave-like fluctuations with the distance from the nucleus, reaching ~8% at the distance ~12,000 km. A similar change in polarization was observed in the SED500 filter. After correction for gas contamination, using the dust/gas ratios from spectroscopy made on the same night, the values of polarization appeared to be ~4% in the near-nucleus region (~1.000 km), and reached 11–12% at the distance ~12,000 km in both filters. We also found an effect of nucleus polarization on the polarization of the dust coma in comet Encke in the r-sdss filter. The maximum value of the nucleus contamination was ~0.7%. Changes in polarization and color across the 2P/Encke coma indicate changes in physical properties of the dust particles with the distance from the nucleus. Our Sh-matrix computer simulations of light scattering by Gaussian particles allow us to suggest that the observed trends in color and polarization are mainly result from changing particle size. • We present the results of polarimetric observations of comet 2P/Encke performed at the 6-m telescope on January 23, 2017. • We show that the gas contamination strongly affects the polarization in the continuum. • The contribution of the nucleus polarization to the polarization of dust coma of comet Encke was first determined. • We study behavior of the dust polarization free of the gas and nucleus contaminations across the coma of comet Encke. • Sh-matrix modeling shows that the trends in polarization and color over the coma may be explained by changing particle size. [ABSTRACT FROM AUTHOR]

Published

2020