RU2673128C1 - Method of detecting comet matter and identifying it with source of origin - Google Patents

Abstract

FIELD: sampling; cosmonautics.SUBSTANCE: invention relates to studies of the space environment on board, in particular, orbital stations. According to the method, sampling is carried out from the surface of the station by means of a sterilized and hermetically sealed sampler. Then the latter is hermetically sealed in a vacuum and returned to the Earth. Wipe samples are taken during the calendar period when a particular meteor stream crosses the Earth's orbit, and the station, moving in orbit with a height of at least 100 km, is in this stream. Sampling is performed after the maximum activity of the stream during the time before the completion of the stream activity epoch, equal to 10–25 % of this epoch. Origin of the matter sampled is identified by the established connection of the specific meteor stream with the comet-progenitor.EFFECT: increase the reliability of identification of comet matter with the source of origin.1 cl

Description

The invention relates to space technology, namely, to methods of experimental research in outer space.

The analysis of the matter of astronomical bodies is one of the most informative directions in the study of the Universe. Meteorites for a long time, before the delivery of lunar soil to Earth, were the only samples of extraterrestrial matter available for direct laboratory analysis, which is why they are interesting for science to this day.

Meteorites falling to Earth are fragments, fragments of asteroids. But if meteorics traditionally has historically accumulated and periodically replenished material for research, then cometary matter is in obvious deficit.

The following ways are possible to detect substances of cometary bodies that have fallen into the sphere of the Earth: meteoroids falling in the form of cometary meteorites; cometary debris exploding in the atmosphere and falling asleep with fine particulate matter over large areas in the region of the explosion; cometary nuclei forming impact craters and astroblems as a result of impact on the solid surface of the Earth. The indicated paths are dependent on the factor of randomness; they do not provide a systematic obtaining of material for research. Criteria for identifying the collected material as a cometary substance are only being developed within the framework of a new scientific direction - comet meteoritics.

Knowing the chemical composition of the substance that makes up the nucleus, coma and tail is one of the tasks of studying comets. The remote method of astrospectroscopy is widely used to determine the composition of astronomical objects. However, the spectrum of the photometric core can simply be a reflected solar or emission molecular spectrum. The reflected solar spectrum does not report anything about the chemical composition of the area from which it is reflected - the nucleus of a comet or the dusty atmosphere surrounding the nucleus. The emission gas spectrum carries information about the chemical composition of the gas atmosphere surrounding the core, and also does not report anything about the chemical composition of the surface layer of the core. Direct and indirect research of astronomical objects is the most reliable, but very complex, multi-aspect and extremely costly approach.

Flights to comets are significant actions in the world cosmonautics. In 1986, the domestic probes Vega-1 and Vega-2, the European probe Giotto, the Japanese Suiei and Sygikake, and the American ICE were sent to Halley's comet, but failed to obtain the cometary substance. Spacecraft were already approaching seven different comets, but all such missions boiled down to a quick passage past comets (Tailed Stars. Popular Mechanics, No. 9, September 2004; http: /www.nkj.ru/news/29638/).

Productive in many other respects, the mission to the comet Chyuryumov-Gerasimenko of the Rosetta-Fillet apparatus was also not crowned with the selection of cometary material due to an unsuccessful landing (http: www.spletnik.ru/blogs/kruto/l02316).

The mission of the Stardust apparatus to comet Vilda-2 is known. Onboard the Stardust there was a mass spectrometer for analyzing the composition of dust in real time, collector plates with airgel traps, which were in the open position in January 2004 when sampling dust material from a cometary coma (Tailed Stars. Popular Mechanics, No. 9, September 2004; http: /www.nkj.ru/news/29638/).

In relation to further studies of comets, the Stardust and Rosetta-Fillet projects, the following disadvantages are inherent.

1. The Dr. Marceden catalog of cometary orbits (http: /mirznanii.com/a/komety), published in 2003, contains data on 1,679 different comets, of which 377 are periodic, that is, regularly returning to the Sun. It is incorrect to present the information received in the mentioned projects as common to comets. Investigating a representative number of comets by space expeditions is unlikely to be possible in the foreseeable future due to their complexity and extremely high cost.

2. The long duration of the mission: from the start of “Stardust” in February 1999 (metro Canaveral), to the return of the capsule with the results (January 15, 2006, Nevada) - 7 years; the Rosetta Fillet expedition - 10 years. There is no possibility to carry out systematic and regular studies of various comets.

3. Indirect study of cometary dust. The main object of research was exposed pieces of airgel, as well as pieces of aluminum foil, which were laid out the walls of the cells with airgel. In the same way as a sponge is squeezed, the material was “squeezed” out of the airgel after boiling it in water of high purity and only the extract obtained was examined for the presence of organic matter.

4. Evidence is required that the substances found were part of the cometary substance, since it is quite realistic to contaminate space samples with terrestrial and non-cometary substances for the following reasons:

- non-sterility of the traps themselves;

- pollution of the apparatus during assembly, transportation, start-up;

- degassing of materials on Earth and in flight;

- falling into a trap for 7 years of flight of substances not from a comet;

- the need for isotope analysis to confirm the comet origin of the delivered substance; the task turned out to be extremely difficult due to the tiny size of the samples and the ineffectiveness of using standard methods for this purpose; It took two years to develop the methodology and special equipment with the necessary accuracy and sensitivity.

A known method for the search and detection of microorganisms of cosmic origin, which consists in the fact that they take smear samples from the surface of the geo-orbital station when flying in the orbital orientation mode from surfaces facing in the direction and opposite to the direction of flight, to the Earth and to the zenith, in sections of the orbit in apogee, perigee, during the equinox and solstice (prototype RU 2618603 C2, publ. 01/10/2017). This method coordinates the sample on the surface of the station, in space relative to the Earth and the Sun, according to the place and time of the position in orbit, but is in no way connected with other phenomena and objects of the heavenly situation, which limits the set of sampling targets. (Prototype).

The objective of the invention is to provide a method for detecting cometary substances and the ability to identify cometary substances with a source of origin.

The technical result of the invention is to increase the reliability of the identification of a cometary substance with a source of origin due to the possibility of planning sampling operations in accordance with the calendar terms of the existence of meteoroid streams, taking into account their maximum activity and connection with the progenitor comet.

The technical result of the invention is achieved by the fact that in the method for detecting a cometary substance and identifying it with a source of origin, smear samples are taken from the surface of the orbital station using a sterilized and hermetically insulated sampler on Earth, after which the latter is sealed in vacuum and returned to the Earth, and smear samples selected in a certain calendar period when a particular meteoroid stream crosses the Earth’s orbit, and the station, moving in a geocentric orbit at an altitude not less than 100 km from the Earth’s surface, is in the meteoroid stream, while sampling is performed in the time interval after the maximum activity of the stream for 10-25% of the epoch of activity of the stream before its completion, and the substance of the sample is identified by origin according to the existing established relationship of a particular meteoroid stream with ancestor comet (http://www.astronet.ru/db/msg/1168084).

A swarm of meteoroids is particles of cometary nuclei, coma and tail of comets, that is, cometary matter in the form of a continuous stream crossing the Earth’s orbit at some time interval. It is accepted that the diameter of the stream is greater than the diameter of the Earth, therefore, moving in its orbit, making 15-16 turns around the Earth every day, the station crosses the meteoroid stream at each turn (http://tourabai.kz/dmitriev/; Meteoroids as aerosol sources in the upper the atmosphere / V.G. Kucherenko, P.N. Kozak, Yu.G. Taranukha et al. Optics of the atmosphere and the ocean. 2010, V. 23, No. 11, S. 957-967).

Meteors are traces of the combustion of most particles of a stream at an altitude of 80-100 km (http://ciencia.nasa.gov/; http://www.astronet.ru/db/msg/1168084). Unburned single particles are deposited on the Earth in the form of micrometeorites and are inaccessible for detection.

At a flight altitude of the orbital station — 400 km, a swarm of meteoroids in the age of activity is presented in the form of a saturated stream of unburned particles settling on the surface of the station. During the period of activity, the number of meteoroids in the stream can reach several thousand per day at ZNR≈1 ÷ 150 (Zenithal Hourly Rate) - the average number of meteors that an ideal observer would see with absolutely clear sky and a radiant at its zenith; http : //saros70.narod.ru/meteorshowers.htm; http://wiki-org.ru). Thus, the orbital station, being in the meteoroid stream, is a tool for collecting sedimentary matter.

To date, a direct connection has been established between meteoroid showers and progenitor comets (http: /mirznanii.com/a/komety).

The proposed method for detecting a cometary substance and its identification with a progenitor comet is implemented as follows. Under terrestrial conditions, the probe is sterilized, placed in a sterilized cavity, pressurized and delivered to the orbital station. The orbital station is used as a particle trap and sedimentation object when it is in the meteoroid stream. According to astronomical data, for the calendar period of the existence of a certain meteoroid shower, it is planned that the crew exit to the outer surface of the station. Upon entering outer space, the astronaut removes the sample inlet from the cavity, takes smear samples of the finely dispersed medium of the surface of the orbital station, pressurizes the sample in the cavity in vacuum, then the sample is returned to Earth for research. Samples are sampled during the activity epoch of the flow, after passing the activity maximum for 10–25% of the activity epoch before its completion in order to accumulate sediment. The station’s orbit is more than 100 km and up to 400 km ensures high flow saturation and maximum sedimentary matter. Identification of the substance of the samples with the sources of origin is carried out on the basis of the known relationships of meteoroid streams with comet progenitors.

An example of the use of the invention.

1. On Earth, in specialized conditions, they prepare the device for sampling: sterilize the samplers, place them in sterilized cavities and pressurize.

2. The prepared instruments on the Progress cargo ship are delivered to the ISS and left in storage mode.

3. According to astronomical data (http://wiki-org.ru), calendar periods of activity of meteoroid streams are established, for example, Perseids:

4. Set the optimal sampling interval:

0.1-0.25 era of activity before its completion,

those. 39 (0.1-0.25) ≈4 ÷ 10 days until August 24, 2017

A calendar period of sampling after the maximum activity is planned: August 14-20, 2017. During this period, the ISS orbit is ~ 400 km.

5. On August 17, 2017, the ISS PC crew consisting of cosmonauts F. Yurchikhin and S. Ryazansky launched into outer space and performed smear sampling at 8 points of the ISS surface precisely at a time when a particular stream of Perseid meteoroids crosses the Earth’s orbit, and the ISS, moving in a geocentric orbit at an altitude of> 100 km from the Earth’s surface, is in a meteoroid stream and is an object of sedimentation.

6. Astronauts insulated the samplers in sterile cavities directly overboard the ISS in a space vacuum and returned the instruments to the station for return to Earth in the Soyuz transport ship.

7. In laboratory analysis, the selected samples can be identified as the substance of the tail of the comet-progenitor 1093 Swift-Tuttle (http://wiki-org.ru).

Using the method for detecting cometary matter and identifying it with a source of origin provides the following opportunities and advantages:

1. A material substance selected from a finely dispersed sediment on the surface of the orbital station is provided for analysis.

2. Precipitation on the surface of the station is formed in the process of multiple crossing by the station when the meteoroid stream, which is the tail of the comet, moves in its orbit.

3. Planning of operations for sampling in accordance with the calendar terms of the existence of meteoroid streams, taking into account their maximum activity and connection with the comet-progenitor.

Claims (1)

A method for detecting a cometary substance and identifying it with a source of origin, which consists in the fact that they take smear samples from the surface of the orbital station using a sterilized and pressurized sampler on Earth, after which the latter is sealed in vacuum and returned to Earth, characterized in that swabs are taken in a certain calendar period when a specific meteoroid stream crosses the Earth’s orbit, and the station, moving in a geocentric orbit at a height of at least 100 km from the surface Earth, is in the meteoroid stream, while sampling is performed in the time interval after the maximum activity of the stream for 10-25% of the epoch of activity of the stream before it is completed, and the substance of the sample is identified by origin according to the existing established relationship of a particular meteoroid stream with a progenitor comet.