Statistics While the stream of meteorites reaching Earth remains pretty much constant over time, statistics of meteorite falls show a more or less continuous increase in the number of observed meteorite falls from the end of the 18th century until a significant peak in the 1930s. This steady increase has been described as early as 1963 and has been explained with changing social, scientific and technical circumstances: population growth and higher population density, improving communication, the expansion of scientific institutions, and the increasing organization of meteoritics and greater interest from the general public all raised the likelihood that fireballs would be reported and that fresh meteorites would be deliberately searched for and recovered. The peak during the 1930ies also coincides with increased activity by private collectors, especially
Harvey H. Nininger and
Oscar Monnig who set significant accents in meteorite hunt and research and the foundation of the Society for Research on Meteorites (now known as the
Meteoritical Society) in August 1933, with
Frederick C. Leonard as the first president and Nininger as secretary. The decline in the 1940s is explained by the disruptions caused by World War II, which significantly impaired fieldwork, international cooperation, publication activity and the acquisition of collections. The increase in observed falls since the beginning of the 21st century can be attributed to improved technical and organizational capabilities for detection and recovery, particularly through global and regional fireball networks, satellite detections, meteor reporting websites, weather radar observations, the spread of digital cameras and social media as well as the use of metal detectors, drones and coordinated search teams.
Automated fireball detection devices In April 1959 the meteorite
Příbram was the first meteorite whose trajectory was tracked by multiple cameras recording the associated fireball. The
Ondřejov Observatory in the Czech Republic captured photos of the fireball using eleven widely spaced cameras. With the help of this stereo recording (through triangulation), Přibram's trajectory could be reconstructed quite accurately, aiding its recovery and also - for the very first time - enabling scientists to trace its pre-impact orbit back to the asteroid belt. Eleven years later, the fireball from the
Lost City meteorite, was recorded with four cameras from the
Prairie Meteorite Network operated by the
Smithsonian Astrophysical Observatory, when it fell in
Cherokee County Oklahoma, in January 1970. This was the first time a meteorite was recovered solely on the basis of photographic measurements. In 1977 the meteorite of Innisfree was discovered using photographs taken by the Meteorite Observation and Recovery Program of the
National Research Council of Canada. The fall of Benešov was recorded in 1991, however the meteorite was only recovered in 2011 after the strewnfield was recalculated and metal detectors were used to search for small fragments. The meteorite of Ischgl was found by an Austria forest ranger in 1976 and was kept at home by the finder without undergoing any scientific examination until 2008, when it was classified as a meteorite. Upon review of the archived fireball events photographed by the German fireball camera network, it could be determined, in a study published in 2024, that in November 1970 a fireball event observed by 10 different stations was connected to the fall of the later discovered meteorite. Over the last decades fireball networks consisting of dedicated arrays of cameras were put in operation in several countries. As more automated cameras monitor the night sky and track fireballs, the chances of locating meteorites have increased. Statistics for observed falls by decade are listed in the table in this section. It took more than 30 years for the falls of the first 4 meteorites to be recorded by automated devices, the same amount of falls with documented trajectories as in the single year of 2015. For the period since 2020 the number of meteorite falls reported globally each year has increased on average to more than ten per year, up from about six a year in the 1990s. As of December 2025 there are 75 instrumentally observed recovered meteorites, for which also a pre-impact orbit could be determined. Today, there are several networks of
whole sky cameras recording space rock from different directions, thus making it easier to calculate the impact sites of meteorites and increasing the probability of actually finding material after a meteor has been observed. Among the camera networks are: •
Cameras for All-Sky Meteor Surveillance •
European Fireball Network •
Desert Fireball Network •
FRIPON Video cameras Accidental random fireball records documented by video have increased over the past decades and social media now distributes videos so broadly that a much larger share of falls is being captured and documented. The bright fireball visible for more than 40 seconds was recorded by 15 chance eyewitnesses' video cameras from different locations. Peekskill back then was only the fourth meteorite whose prior orbit could be calculated based on the reconstructed trajectory of the fall. The orbits for the previous falls of Přibram (1959),
Lost City meteorite (1970) and Innisfree (1977) had been determined based on photographs. Peekskill, however, was the first fall documented by motion-picture footage. Video cameras have since become widespread with the rise of surveillance or traffic cameras, ski-resort webcams, dashboard and doorbell cameras and smart phones, which have all been used to capture fireballs in connection with recovered meteorites. Among the most spectacular falls observed by numerous cameras is the
Chelyabinsk meteor from February 2013. The fall of the meteorite in
Novo Mesto, Slovenia, in February 2020 was captured by dashcams, security cameras and even a camera mounted on a cyclist's helmet. The footage was used by astronomers to triangulate the meteorite's trajectory. The fall of the
Charlottetown meteorite in 2024 was the first case, where the actual moment of the impact on the ground was recorded with video including audio. The sound of the meteorite shattering upon impact has been described as similar to the sound of breaking ice.
Radar detection Weather radar has become a useful aid for locating meteorites after observed fireballs because it can detect descending fragments of the meteorite during the
dark flight-phase – that is, the phase of a meteorite's descent when its speed has been slowed by atmospheric drag to the point that it no longer emits visible light and the fragments reach
terminal velocity. Radar-derived echoes from falling stones can help determine whether an observed fireball event has produced meteorites large enough to be recovered on the ground. Radar data in combination with weather data can be used to reconstruct a fall's final trajectory in order to calculate a possible
strewn field. This allows people searching for meteorites to focus their search efforts more efficiently than by relying only on traditional methods such as eyewitness accounts, recordings from security cameras and other video sources. Targeted searches have improved the chances to quickly collect minimally weathered specimens that are scientifically valuable for studying the composition and history of their parent bodies. The fall of the Ash Creek meteorite in February 2009 was the first time when data from weather radar was used to locate meteorites on the ground. Among the radar-enabled recoveries of meteorites is also the fall of the
Sutter's Mill meteorite. Archived radar data has also been used retrospectively to identify radar signals of falling fragments for earlier meteorite falls such as Worden in 1997 or Indian Butte in 1998. Most of the radar detections of meteorite falls have occurred in the United States, where the data produced by the
NEXRAD system is publicly available online almost in real time and archived since the introduction of the system in the 1990s. As of 2025 there are 32 meteorite falls where evidence of falling debris was found in NEXRAD data. Among them are also falls outside the United States, such as the Grimsby meteorite, a fall from 2019 in Cuba, both of which were within the detection radius of NEXRAD stations.
Astronomical observations before impact In October 2008, the observation of asteroid
2008 TC3 turned into the first meteorite whose impact had been predicted. The asteroid on a collision course with Earth had been discovered by
Richard Kowalski with the automated
Catalina Sky Survey telescope at
Mount Lemmon Observatory, about 20 hours before it entered the atmosphere and fell in the
Nubian Desert in
Sudan. The fall of the meteorite could be observed from a distance of 1,400 km by pilots of a KLM passenger plane flying over Chad and a webcam from a beach in Egypt from a distance of 725 km. Eyewitnesses on the ground in
Wadi Halfa and at "train station number six" (Arabic: al-Maḥaṭṭa Sitta) in northern Sudan at 05:46 am local time observed a meteor and heard explosion sounds. Two months after the fall, an expedition organized by the
University of Khartoum found the first fragments of the meteorite. Since the observed fall of the Almahata Sitta meteorite, 10 more asteroids have been added to the
list of predicted asteroid impacts on Earth which impacted earth after discovery and orbit calculation that predicted the impact in advance. Among them are 3 more observed falls, where fragments of the meteorites could be recovered: • Meteorite Motopi Pan - (Asteroid
2018 LA) • Meteorite Saint-Pierre-le-Viger - (Asteroid
2023 CX1) • Meteorite Ribbeck - (Asteroid
2024 BX1) == Historic records of meteors and meteorites ==