From Chelyabinsk to Cuba: The Meteor Connection
On February 1, 2019, a bright meteor crossed the sky over Cuba just in the middle of the day. The phenomenon, which was followed by a “smoke trail” (a characteristic cloud left by the burn in the atmosphere of a meteoroid) and a sonic boom, was witnessed by thousands of locals and tourists in the region of Pinar del Rio (western side of the island).
Almost at the same time of the impact, a cruise ship was leaving the Havana harbor and on board, Rachel Cook, an American tourist and vlogger, was making a time-lapse of the undocking process. Without knowing, she was recording one of the few videos known to date of the falling meteor. Meanwhile, 400 km away, in Ft. Myers beach, Florida, a web cam of the EarthCam network was filming the midday activities in the beach. Luckily, the camera was aimed at the right direction to record the meteor from afar.
Just a couple of minutes after the event, social networks, especially Instagram and Twitter, received a flood of tens of videos and pictures, taken from the island, most of them showing the smoke trail left by the meteor.
One of those videos was particularly interesting. It was recorded in one of the main streets of the city of Pinar del Rio, and showed tens of people in the street contemplating with awe the remnant cloud. Although the video does not show the meteor, it was full of details about the place and time when it was recorded.
All these events recalled the incredible experience of the Chelyabinsk meteor in 2013, when a super bolide, 400 brighter than the Cuba meteor (as NASA revealed a few days after the Cuba impact), hit the atmosphere over a populated area in western Russia, becoming the only event of its kind witnessed by humans in almost a century.
Just a couple of days after the Chelyabinsk impact, a team of astronomers of the Institute of Physics in the University of Antioquia, led by Professor Jorge I. Zuluaga, achieved to reconstruct the trajectory of the Chelyabinsk meteor using exclusively videos of the phenomenon published on YouTube.
Although many other teams in Russia, Czech Republic, Canada and US, achieved also to reconstruct the trajectory using more sophisticated methods and data, the ingenious use of the Colombian Astronomers of the information available on the Internet was well received by the whole world marking an inflection point in the role that social networks and in general citizen science, could have for studying this type of phenomena.
Today, just a week after the event and almost exactly 6 years after the Chelyabinsk impact, the same Colombian scientific team, using again information available on the internet, applied their methods to reconstruct the trajectory of the Cuban meteor. Their results have been included in a scientific manuscript just submitted to a peer review journal. A preprint of the manuscript is available in the Cornell University arXiv lists.
“We were very lucky that at least three relatively reliable videos, including one with an incredible quality, could be available on the Internet in such a short time,” explains Zuluaga and he adds, “Reconstructing the trajectory of a meteor requires at least three observers on the ground. Although several satellite images were recorded and also available on line, without observations from the ground the precise reconstruction is not feasible.”
According to the reconstruction made by the Colombian astronomers, the object producing the meteor over Cuba, starts its trajectory inside the atmosphere at an altitude of about 76.5 km above the Caribbean Sea, over a point 26 km to the southwest of the San Felipe Keys (Cuba).
The speed of the rock at its contact with the atmosphere was 18 km/s (64,800 km/h). With such a velocity, the thin air of the high atmosphere was not enough to stop the object, although it was enough to heat it until the rock started to shine.
The rock continued its path in an almost straight line until a height of around 27.5 km. It was at about that altitude that the smoke trail, observed by thousands in Cuba and in satellite images, started to develop. Zuluaga and coauthors estimate that the cloud seen in Pinar del Rio correspond to a small part of the trajectory of the meteor (corresponding to altitudes between 26 and 22.5 km). According to the footage on that city and the reconstruction of the Colombians, the airburst suddenly ended at about 22 km.
From there on, hundreds of small fragments who survived the atmospheric ablation, fell in many directions without emitting any light (dark flight). Although most of these small rocks probably ended up in the forests of the Vinales Natural Park, some of them hit several houses in the Vinales Valley, close to a touristic landmark, “El Mural de la Prehistoria,” 6 km away from the main path of the object. If a big fragment survived the ablation, it probably landed in the ocean on the northwestern coast of the island.
After reconstructing the trajectory in the atmosphere, the Colombian astronomers “played back” the impact and found that the culprit, a rock with an estimated size of several meters and a weight of about 360 tons, came from an eccentric orbit around the Sun with an average distance to our star of 1.3 astronomical units (1 astronomical unit = 150 million km).
Before impacting the Earth, the rock completed a turn around the Sun every 1.32 years. All that came to an end on February 1, 2019, when both the rock and Earth found themselves at the same point in space, at the same time. The worse part was for the rock!
But reconstructing the trajectory of the meteor was not enough for the Colombian Astronomers. Several groups in the world are probably working right now on their own estimations, some of them using precise satellite data or information from infrasound networks. As the Chelyabinsk impact taught us, this event attracts the attention of many scientists and it is probable that other works will be published about the impact on the following weeks or months.
More interestingly, the astronomers used their results to test a method that Zuluaga and Mario Sucerquia, who was also a coauthor of this work, developed recently to study asteroid impacts against Earth and the Moon. The method, called Gravitational Ray Tracing (GRT), applies several algorithms originally devised for the computer graphics industry.
In GRT Earth is not hit by asteroids but it is a source of them. Many “artificial rocks” are launched (in a simulated environment) into thousands of directions in the sky and with different speeds, from a certain geographical location (a beach in the northwest of Cuba or a valley on the Moon).
The mock rocks that end up in orbits around the Sun similar to already discovered asteroids are flagged as potential impactors. The rocks ending up in orbits which are not typical of Near Earth Objects (NEOs) are flagged as unnatural objects.
Using the rocks that are flagged as potential asteroids, the astronomers are able to create maps in the sky of the directions from which a real asteroid could arrive. Or at least this is what the theory of Zuluaga and Sucerquia states.
The Colombian astronomers found that their theoretical method, “predicted” what Cubans saw: a rock coming from the South in a trajectory inclined around 30 degrees with respect to the horizon.
In order to check if this result was not just the product of chance, they perform a similar calculation but in the case of the Chelyabinsk event. Again, the method predicted that at the time and location of the Russian impact, the most probable region in the sky from where an asteroid could arrive was looking towards the northeast, at an elevation of 20 degrees. The actual object appeared almost in the direction of the east and at exactly 20 degrees of elevation.
But still, if you toss a coin twice, the probability that just by chance you obtain two faces is not really low. The coincidence between the predictions of GRT and the actual conditions of the Chelyabinsk and Cuba impact could also be random. However, it could also reveal a deeper truth, namely, the fact that we could predict in advance the direction in the sky from which a meteor could arrive into our city (if that impact actually occur).
“Only after the recent digital boom we have realized how frequent and potentially hazardous could the impact of small meteoroids on populated areas,” tells Mario Sucerquia. He adds, “Sadly we are not yet able to defend our society against these threats; our work suggests that in principle we could be prepared, at least with some knowledge, for future impacts”.
For Prof. Pablo Cuartas, coauthor of the paper, “The relatively small size of meteoroids like those that fell in Chelyabinsk and Cuba, made them practically undetectable before the impact,” and he adds, “Since detection is almost impossible, the risk that damaging events like this happen over very populated areas is very high; our results suggest that we can predict in advance at least from which direction they will come.” Finally, he sentences, “We should be prepared for the next projectile!” Mario Sucerquia is even more direct: “We should check impact probabilities all the time at least in populated areas; doing this as part, for instance, of a public protocol, may help us to take preventive measures in the face of impact threats.”
Research Report: “Can We Predict the Impact Conditions of Meter-sized Meteoroids?” Jorge I. Zuluaga, Pablo A. Cuartas-Restrepo, Jonathan Ospina, and Mario Sucerquia, submitted to Monthly Notices of the Royal Astronomical Society Letters
This follows the finding, announced in November 2018, of a 19-mile-wide crater beneath Hiawatha Glacier – the first meteorite impact crater ever discovered under Earth’s ice sheets. Though the newly found impact sites in northwest Greenland are only 114 miles apart, at present they do not appear to have formed at the same time.
If the second crater, which has a widt … read more