The history of tornado research spans back centuries, with the earliest documented tornado occurring in 200 and academic studies on them starting in the 18th century. This is a timeline of government or academic research into tornadoes.
The earliest-known German tornado struck Freising (modern day Germany) in 788.[2][3] The earliest-known Irish tornado appeared on April 30, 1054, in Rostella, near Kilbeggan. The earliest-known British tornado hit central London on October 23, 1091, and was especially destructive, with modern research classifying it as an F4 on the Fujita scale.[4]
After the discovery of the New World, tornadoes documentation expanded into the Americas. On August 21, 1521, an apparent tornado is recorded to have struck Tlatelolco (present day Mexico City), just two days before the Aztec capital's fall to Cortés. Many other tornadoes are documented historically within the Basin of Mexico.[5] The first confirmed tornado in the United States struck Rehoboth, Massachusetts, in August 1671.[6][7][8] The first confirmed tornadic death in the United States occurred on July 8, 1680, after a tornado struck Cambridge, Massachusetts.[9]
18th century
The first case study on a tornado took place following the violent 1764 Woldegk tornado, which struck around Woldegk, Duchy of Mecklenburg-Strelitz, Holy Roman Empire (modern-day Germany).[10] Between 1764 and 1765, German scientist Gottlob Burchard Genzmer published a detailed survey of the damage path from the tornado. It covers the entire, 33 km (18.6 mi) long track and also includes eyewitness reports as well as an analysis of the debris and hail fallout areas. Genzmer calls the event an "Orcan" and only compares it to waterspouts or dust devils.[11][12] Based on the damage survey, modern day meteorologists from the ESSL were able to assign a rating of F5, on the Fujita scale, and T11 on the TORRO scale, making it the earliest known F5 tornado worldwide.[10] The T11 rating on the TORRO scale also places this event among the most violent tornadoes ever documented worldwide.[10]
19th century
In 1838, the earliest recorded Asian tornado struck near the city of Calcutta in present-day West Bengal, India. It was described as moving remarkably slow across its 16-mile (26 km) path southeast over the span of 2 to 3 hours. It was recorded to cause significant damage to the area, including 3.5-pound (1.6 kg) hail being observed at the Dum Dum weather observatory.[13]
Between 1839 and 1841, a detailed survey of damage path of significant tornado that struck New Brunswick, New Jersey, on June 19, 1835, which was the deadliest tornado in New Jersey history, occurred. The path was surveyed by many scientists on account of its location between New York City and Philadelphia, including early tornado theorists James Pollard Espy and William Charles Redfield. Scientists disagreed whether there was whirling, convergent, or rotational motion. A conclusion that remains accurate today is that the most intense damage tends to be on right side of a tornado (with respect to direction of forward movement), which was found to be generally easterly).[14][15]
In 1840, the earliest known intensive study of a tornadic event published in Europe, by French scientist Athanase Peltier.[16]
In 1865, the first in India and earliest known scientific survey of a tornado that analyzed structure and dynamics was published in 1865 by Indian scientist Chunder Sikur Chatterjee. The path damage survey of a tornado that occurred at Pundooah (now Pandua), Hugli district, West Bengal, India, was documented on maps and revealed multiple vortices, the tornadocyclone, and direction of rotation,[17] predating work by John Park Finley, Alfred Wegener, Johannes Letzmann, and Ted Fujita.
In 1886, Lieutenant Jno. P. Finley in the United States Army Signal Corps, under official orders from the United States military, wrote a case study on tornado outbreak which occurred between September 12–18, 1886. Finley studied 26 tornadoes which occurred during the outbreak.[18]
1895
In 1895, D. Fisher with the United States Weather Bureau (USWB) published a case study on a tornado which struck Augusta, Georgia, on March 20, 1895, along with a twin tornado and a satellite tornado, which also struck Augusta.[19] Two months later, the United States Weather Bureau conducted a short case study on the tornado outbreak of May 3, 1895, tracking each of the 18 tornadoes that occurred during the outbreak.[20] A month later, meteorologists at the United States Weather Bureau conducted a case study on a tornado which struck Cherry Hill, New Jersey, and a tornado which struck Woodhaven, Long Island, New York, on July 13, 1895. The case study included a damage survey and meteorological analysis of the storms.[21]
1896
In 1896, H. C. Frankenfield with the United States Weather Bureau's local forecast office in St. Louis, conducted a case study on the 1896 St. Louis–East St. Louis tornado, which included a damage survey and meteorological analysis of the tornado and associated storm.[22] Following the study by Frankenfield, a special case study was conducted by Julius Baier, a civil engineer in St. Louis to address an estimation made by Frankenfield. In his study, Baier stated that the tornado's center crossed directly over a barometer, which recorded a reading of 671 millimetres of mercury (895 mb). In the study, it was also documented that Baier, along with professor F. E. Nipher, tested the barometer and saw no apparent ways of an inaccurate reading.[23]
Also in 1896, Norman B. Conger, an inspector with the United States Weather Bureau, conducted and published a case study on the 1896 Thomas, Michigan tornado, based on "all reliable, available sources". Conger's report also contained a map created by E. F. Hulbert. Following the tornado, Michigan governor John Treadway Rich created a committee to assess the damage and collect further information about the tornado.[24]
1897
In June 1897, Cleveland Abbe, a PhD meteorologist and professor at Columbian University, published one of the first tornadic frequency tables for each state in the United States, which included the annual average per state as well as the average per 10,000 square miles (26,000 km2). In the table, it was noted that Kansas was the leading state for tornadoes, with an annual average of 6.38 tornadoes, followed by Illinois with an annual average of 4.94 tornadoes. The only states documented with an annual average of 0 tornadoes was Alaska, Delaware, Idaho, Oregon, Rhode Island, Utah, and Washington.[25] In July 1897, M. C. Walsh with the La Salle Institute reported the beginning of the 1896 St. Louis–East St. Louis tornado's track, which included a description of "two long, heavy black masses of cloud, one moving from the southwest, the other curving from the northeast" with them meeting "at a height of about 1,000 feet (330 yd; 300 m)".[26]
1898
In February 1898, J. J. O'Donnell, an observer for the United States Weather Bureau, published a detailed meteorological case study and damage analysis on a violent tornado which struck Fort Smith, Arkansas, on January 12, 1898. Prior to being struck by the tornado, O'Donnell observed a barometer which read a pressure of 28.846 inches of mercury (976.8 mb). O'Donnell also recorded the order-of-sequence of what an approaching tornado sounds like: "a gurgling noise...like water rushing rushing out of a bottle, followed immediately by a rumbling, such as that made by a number of heavy carriages rolling rapidly over a cobblestone pavement, and finally like a railroad train." O'Donnell later stated these three sounds, in sequence is the "tornado roar".[27] This sequence of sounds documented by O'Donnell, particularly the sound of a train, is the described sound of a tornado by people, even in the 21st century.[28]
In May 1898, Willis L. Moore, the chief of the United States Weather Bureau, created a map, which was later published by an order from the United States Secretary of Agriculture, of meteorological observations across the United States as well as the tracks of tornadoes which occurred on May 17, 1898.[29] In July 1898, Arthur E. Sweetland wrote a case study, including a damage survey and analysis, for a tornado which struck Hampton Beach, New Hampshire, on July 4, 1898.[30] In December 1898, Dr. B. F. Duke, along with Dr. Cleveland Abbe, published a paper regarding a theory on how tornadoes form after Duke observed the formation of a tornado near Pascagoula, Mississippi, in April 1894.[31]
1899
In April 1899, Dr. Cleveland Abbe, along with Professor A. W. Baker and E. L. Dinniston, published an article regarding the characteristics of tornadoes. In the study and analysis, Abbe discovered that tornadoes in the United States rotate counterclockwise, just the same as a large low-pressure system. Abbe also stated that this rotation rule for tornadoes "is almost invariable".[32] Also in April, Abbe published an article along with the Iowa State Register and Iowa Weather and Crop Service, stated the number of tornadoes across the United States was not truly increasing and than any numeric increase in tornado count was strictly due to the increase of newspaper and telegraph coverage in the United States. It was also stated that tornadoes are now documented almost entirely within 24-hours, so no meteorological phenomenon is causing an increase in tornado counts. Abbe also stated anything to the contrary was a "popular mistake".[33]
In April 1899, the Chicago Tribune wrote to the United States Weather Bureau via a news article posing the question on why tornado warnings are not sent out via telegraphs or even the telephone to warn the local population in the path. Cleveland Abbe responded by saying "it is certain that if any such arrangement were possible, the Weather Bureau would have done this many years ago" along with "we must remember that the destructive areas of tornadoes, and even of thunderstorms, are so small that the chance of being injured is exceedingly slight" and that "we do not attempt to prevent that which is inevitable".[34]
In June 1899, U.S. Weather Bureau Oklahoma section director J. I. Widmeyer published that long-range forecasters in Oklahoma were sounding "unnecessary tornado alarms" due to "ignorant predictions" to residents in Oklahoma and that they were causing "frightened men, women, and children" to take shelter, despite no tornadoes occurring. Cleveland Abbe added on to the publication by Widmeyer saying, "It is unnecessary to resort to the caves and cellars, or to stop our ordinary avocations for fear of a tornado, until we see the cloud in the distance, or are positively certain that one is about to pass near us".[35]
In November 1900, S. C. Emery with the United States Weather Bureau conducted a case study, including detailed damage surveys, for a small tornado outbreak in Tennessee, Mississippi and Arkansas on November 19, 1900. In the study, Emery surveyed and mapped that one of the tornadoes "divided" into two nearly parallel parts, or that it had a "zig zag" motion, as some buildings were not damaged and others destroyed. Emery also stated he was "inclined to believe the latter explanation as more reasonable". Emery also noted one of the tornadoes had an average forward speed of 60 mph (97 km/h) and that a separate tornado travelled 215 miles (346 km).[38]
1901
In 1901 and later again in 1906, Frank H. Bigelow, chief of the United States Weather Bureau, calculated and published formulas to find the rotational speed of a tornado based on the height above sea level. In his study, Bigelow studied a waterspout off the coast of Cottage City, Massachusetts.[39][40] Bigelow's formula went on to help Alfred Wegener, a leading geophysicist, atmospheric scientist, and an Arctic explorer, develop the hypothesis that tornadoes can form off of a gust front.[41]
In May 1902, S. C. Emery with the United States Weather Bureau published a case study and damage survey for a 118 mi (190 km)-long tornado which struck northeastern Mississippi and northwestern Alabama on March 28, 1902.[42]
1903
In June 1903, J. B. Marbury, the director of the United States Weather Bureau office in Atlanta, Georgia, published a case study on a tornado which struck Gainesville, Georgia, on June 1, 1903. Marbury stated the tornado itself had a "characteristic greenish hue" and that it was "one of the most destructive tornadoes in the history of Georgia".[43]
1904
In January 1904, Frank P. Chaffee, the director of the United States Weather Bureau office in Montgomery, Alabama, published a case study on a violent tornado which struck Moundville, Alabama, on January 22, 1904. The study included details on wind speed measurements of the tornado, reaching up to 60 miles per hour (97 km/h), taken around Birmingham, Alabama.[44] In July 1904, Albert Ashenberger published a case study on a tornado in Mobile County, Alabama, on May 30, 1904.[45]
1905
In March 1905, Frank P. Chaffee with the U.S. Weather Bureau conducted a damage survey on a tornado in eastern Alabama on March 20, 1905.[46] In August 1905, C. M. Strong, the director of the United States Weather Bureau office in Oklahoma published a detailed case study for a damage survey of the violent and deadly 1905 Snyder, Oklahoma tornado, which occurred on May 10, 1905.[47]
1906
In March 1906, Lee A. Denson with the U.S. Weather Bureau published a case study on a tornado which struck Meridian, Mississippi, on March 2, 1906. The center of the tornado passed within 250 yards (230 m) of the local U.S. Weather Bureau office, allowing for pressure, temperature, and wind speed measurements of up to 64 mph (103 km/h) close to the tornado.[48] In May 1906, Andrew Noble along with H. A. Hunt, an Australian Government meteorologist, published a case study on a destructive tornado which sturck North Sydney, New South Wales, Australia, on March 27, 1906.[49]
1920s
On March 18, 1925, the violent Tri-State tornado occurred, killing 695 people, while traveling 219 miles (352 km) over a period of 3 hours and 45 minutes. At one point, the tornado was moving with a forward speed of 73 miles per hour (117 km/h), setting the record as the fastest forward moving violent tornado in history. The tornado also became the deadliest tornado in United States history as well as the longest traveled tornado in history. All of these records have led the Tri-State tornado to be extensively surveyed and analyzed by academic researchers.[50][51][52]
On April 21, 1946, a tornado struck the area in and around Timber Lake, South Dakota. The United States Weather Bureau published a paper later in the year stating the width of this tornado was 4 miles (6.4 km), which would make this the widest tornado ever documented in history.[54]
1950s
In September 1958, E.P. Segner Jr. published a case study on the 1957 Dallas tornado. In the analysis, Senger estimated that the tornado had winds at least up to 302 mph (486 km/h), due to the obliteration of a large billboard.[55] The 1957 Dallas tornado was also studied extensively by the Severe Weather Forecast Unit in Kansas City, who proved several prominent theories about tornadoes were wrong. One of these-then proven false theories was that all air and debris flowed inward into the funnel and then upward, but on the outside edges of the funnel debris and people were even lifted. Among the studies was the first-ever photogrammetric analysis of wind speeds in a tornado. The film of the tornado is still regarded as being of exceptionally high quality and sharpness. Additionally, structural surveys following this and the Fargo tornado later in the year provided data that contributed to the development of the Fujita scale.[56][6]
1960s
On June 25, 1967, the Royal Netherlands Meteorological Institute (KNMI) issued a weather forecasting calling for tornadoes, which became the first-ever tornado forecast in Europe.[57]
1970s
In 1971, Ted Fujita, with the University of Chicago, in collaboration with Allen Pearson, head of the National Severe Storms Forecast Center/NSSFC (currently the Storm Prediction Center/SPC), introduced the Fujita scale as a way to estimate a tornado's intensity. Following the scale's introduction, tornadoes across the United States were retroactively rated on the scale going back to 1950, and the National Oceanic and Atmospheric Administration (NOAA) formally adopted the scale. The scale was updated in 1973, taking into account path length and width, becoming the modern-day Fujita scale.[58] Ted Fujita rated tornadoes from 1916 to 1992, however, pre-1949 rating were not formally accepted by the U.S. government.[59][60]
Between April 3–4, 1974, a catastrophic Super Outbreak occurred across the United States, which produced 148 tornadoes in a 24-hour period and led to the deaths of 335 people.[61] The 1974 Super Outbreak was extensively studied by Ted Fujita along with other researchers.[62][63][64] Following the outbreak, Fujita and a team of colleagues from the University of Chicago, University of Oklahoma, and National Severe Storms Laboratory, undertook a 10-month study of the 1974 Super Outbreak. Along with discovering new knowledge about tornadoes, such as downbursts and microbursts, and assessing damage to surrounding structures, the violent tornado which struck Xenia, Ohio, was determined to be the worst out of 148 storms.[65][66] Fujita initially assigned a preliminary rating of F6 intensity ± 1 on the Fujita scale,[67] before stating F6 ratings were "inconceivable".[68]
1990s
In 1993, Thomas P. Grazulis, head of The Tornado Project and regarded tornado expert, published Significant Tornadoes 1680–1991 in which, he documented all known significant tornadoes, which he considered F2–F5 intensity or one that caused a death, in the United States going back to 1680. He also retroactively rated significant tornadoes in the United States going back to 1880.[6] This book, also called the "de facto bible of U.S. tornado history" is widely cited by meteorologists, historians, and by the United States government.[69]
In 2002, a Service Assessment Team was formed by the United States government to assess the quality of forecasts and post-tornado assessments conducted by the National Weather Service (NWS) office in Baltimore/Washington for the 2002 La Plata tornado. Their assessment and findings, released in September 2002, found that the local NWS office failed to indicate the initial findings of F5 damage on the Fujita scale was "preliminary" to the media and public.[70] The Service Assessment Team also recommended the National Oceanic and Atmospheric Administration require local National Weather Service offices to only release "potentially greater than F3" if F4 or F5 damage was suspected and to only release information regarding F4 or F5 damage after Quick Response Team (QRT) had assessed the damage.[70] Following the report, the National Weather Service created a national Quick Response Team (QRT), whose job is to assess and analyze locations believed to have sustained F4 or F5 damage on the Fujita scale.[70]
In February 2007, the Enhanced Fujita scale is formally released and put into use across the United States, replacing the Fujita scale.[71][72] In May, the 2007 Greensburg tornado family occurred, producing a tornado family of 22 tornadoes, including the first tornado to receive the rating of EF5 on the Enhanced Fujita scale; the 2007 Greensburg tornado.[73]
In August 2008, Timothy P. Marshall, a meteorologist and structural and forensic engineer with Haag Engineering, Karl A. Jungbluth with the National Weather Service, and Abigail Baca with RMS Consulting Group, published a detailed damage survey and analysis for the 2008 Parkersburg–New Hartford tornado.[74] In October, Matthew R. Clark with the United Kingdom's Met Office published a case study on a tornadic storm in southern England on December 30, 2006.[75]
2010s
In April 2011, the Super Outbreak, the largest and costliest tornado outbreak ever to occur, produces 360 tornadoes across the Midwestern, Southern, and Northeastern United States, leading to dozens of academic studies.[76][77][78] On May 22, 2011, a violent EF5 tornado impacts Joplin, Missouri, killing 158 people, becoming the deadliest modern-day tornado in history.[79]
In April 2013, Environment Canada (EC) adopts a variation of the Enhanced Fujita scale (CEF-scale), replacing the Fujita scale across Canada.[80] In May, a violent EF5 tornado impacts Moore, Oklahoma, marking the last tornado to receive the rating of EF5 on the Enhanced Fujita scale.[81] A few days later, a violent tornado impacts areas around El Reno, Oklahoma.[82] The University of Oklahoma's RaXPol mobile Doppler weather radar, positioned at a nearby overpass, measured winds preliminarily analyzed as in excess of 296 mph (476 km/h). These winds are considered the second-highest ever measured worldwide, just shy of the 302 ± 22 mph (486 ± 35 km/h) recorded during the 1999 Bridge Creek–Moore tornado.[83][84] The El Reno tornado also had a documented width of 2.6 miles (4.2 km), which the modern-day National Weather Service stated was the widest tornado ever recorded, despite the United States government documenting and publishing about a tornado that was 4 miles (6.4 km) wide in 1946.[85][86]
In 2021, Nate DeSpain, with the University of Louisville and Tom Reaugh, with the National Weather Service, published a detailed damage survey and analysis of the 1890 Louisville tornado, where it was rated F4 on the Fujita scale.[95]
2022
Between March 2022 and April 2023, the Propagation, Evolution, and Rotation in Linear Storms (PERiLS) Project occurred. The project involved over a hundred people from sixteen organizations and was described as "the largest and most ambitious study focused on improving [the] understanding of tornadoes associated with linear storms." The PERiLS Project was funded by two grants from the National Science Foundation, three grants from the NOAA's VORTEX-USA program, and a grant from the United States Department of Commerce.[96] Also in March 2022, the National Weather Service published a new damage survey and analysis for the 2012 Henryville EF4 tornado, where a "possible EF5 damage" location is identified and discussed.[97]
Days later, Timothy Marshall, a meteorologist, structural and forensic engineer; Zachary B. Wienhoff, with Haag Engineering Company; Christine L. Wielgos, a meteorologist at the National Weather Service of Paducah; and Brian E. Smith, a meteorologist at the National Weather Service of Omaha, publish a detailed damage survey and analysis of the 2021 Western Kentucky EF4 tornado. In their conclusion, the researchers state, "the tornado damage rating might have been higher had more wind resistant structures been encountered. Also, the fast forward speed of the tornado had little 'dwell' time of strong winds over a building and thus, the damage likely would have been more severe if the tornado were slower."[100]
In March 2024, Anthony W. Lyza, Matthew D. Flournoy, and A. Addison Alford, researchers with the National Severe Storms Laboratory, Storm Prediction Center, CIWRO, and the University of Oklahoma's School of Meteorology, published a paper where they state, ">20% of supercell tornadoes may be capable of producing EF4–EF5 damage" and that "the legacy F-scale wind speed ranges may ultimately provide a better estimate of peak tornado wind speeds at 10–15 m AGL for strong–violent tornadoes and a better damage-based intensity rating for all tornadoes". In their conclusion, the researchers also posed the question: "Does a 0–5 ranking scale make sense given the current state of understanding of the low-level tornado wind profile and engineering of structures?"[112]
In April 2024, the European Severe Storms Laboratory and the Czech Hydrometeorological Institute, along with seven other European organizations, published a detailed damage survey and analysis on the 2021 South Moravia tornado using the International Fujita scale.[113] Also in April, Timothy A. Coleman, with the University of Alabama in Huntsville (UAH), Richard L. Thompson with the NOAA Storm Prediction Center, and Dr. Gregory S. Forbes, a retired meteorologist from The Weather Channel published an article to the Journal of Applied Meteorology and Climatology stating, "it is apparent that the perceived shift in tornado activity from the traditional tornado alley in the Great Plains to the eastern U.S. is indeed real".[114][115] On April 26, a Doppler on Wheels (DOW) mobile radar truck measured 1-second wind speeds of approximately 224 mph (360 km/h) at a height of ~282 yards (258 m) as a tornado passed near Harlan, Iowa, causing widespread destruction.[116][117] On April 30, strong tornado near Hollister, Oklahoma passed close to a NEXRAD radar. The radar measured a tornado vortex signature with a gate-to-gate of 260 miles per hour (420 km/h) about 600 feet (200 yd; 180 m) above the surface.[118][119] On May 21, a violent EF4 tornado struck the town of Greenfield, Iowa. As the tornado moved through the town, a Doppler on Wheels measured winds of at least >250 mph (400 km/h), "possibly as high as 290 mph (470 km/h)" at 48 yards (44 m) above the surface.[120] Pieter Groenemeijer, the director of the European Severe Storms Laboratory, noted that "on the IF-scale, 250 mph measured below 60 m above ground level is IF4 on the IF-scale, 290 mph is IF5."[121] The peak wind speed estimate was revised to between 309 mph (497 km/h) and 318 mph (512 km/h), a figure "among the highest wind speeds ever determined using DOW data", on June 22, 2024.[122]
In May 2024, researchers with the University of Western Ontario's Northern Tornado Project and engineering department conducted a case study on the 2018 Alonsa EF4 tornado, the 2020 Scarth EF3 tornado, and the 2023 Didsbury EF4 tornado. In their case study, the researchers assessed extreme damage caused by the tornado which is ineligible for ratings on the Canadian Enhanced Fujita scale or the American Enhanced Fujita scale (EF-scale). In their analysis, it was determined all three tornadoes caused damage well-beyond their assigned EF-scale ratings, with all three tornadoes having EF5-intensity winds; Alonsa with 127 metres per second (280 mph; 460 km/h), Scarth with 110–119 metres per second (250–270 mph; 400–430 km/h), and Didsbury with 119 metres per second (270 mph; 430 km/h). At the end of the analysis, the researchers stated, "the lofting wind speeds given by this model are much higher than the rating based on the ground survey EF-scale assessment. This may be due to the current tendency to bias strong EF5 tornadoes lower than reality, or limitations in conventional EF-scale assessments".[123] On May 24, a Doppler on Wheels observed and recorded data of a large and long-lived EF2 tornado near Duke, Oklahoma.[124]
^Dr. R. Hennig, Katalog bemerkenswerter Witterungsereignisse. Berlin 1904; Originalquellen: Aventinus (Turmair), Johannes (gest. 1534): Annales Boiorum. Mit Nachtrag. Leipzig 1710; Annales Fuldenses, Chronik des Klosters Fulda. Bei Marquard Freher: Germanicarum rerum scriptores ua Frankfurt aM 1600–1611)
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^De, S.; A. K. Sahai (2019). "Was the earliest documented account of tornado dynamics published by an Indian scientist in an Indian journal?". Weather. 75 (4): 120–123. doi:10.1002/wea.3485. S2CID149888981.
^"Update On May 31 El Reno Tornado". National Weather Service Norman, Oklahoma. National Oceanic and Atmospheric Administration. June 4, 2013. Archived from the original on August 5, 2012. Retrieved June 4, 2013.
^ abKosiba, Karen A.; Lyza, Anthony W.; Trapp, Robert J.; Rasmussen, Erik N.; Parker, Matthew; Biggerstaff, Michael I.; Nesbitt, Stephen W.; Weiss, Christopher C.; Wurman, Joshua; Knupp, Kevin R.; Coffer, Brice; Chmielewski, Vanna C.; Dawson, Daniel T.; Bruning, Eric; Bell, Tyler M.; Coniglio, Michael C.; Murphy, Todd A.; French, Michael; Blind-Doskocil, Leanne; Reinhart, Anthony E.; Wolff, dward; Schneider, Morgan E.; Silcott, Miranda; Smith, Elizabeth; Aikins, oshua; Wagner, Melissa; Robinson, Paul; Wilczak, James M.; White, Trevor; Bodine, David; Kumjian, Matthew R.; Waugh, Sean M.; Alford, A. Addison; Elmore, Kim; Kollias, Pavlos; Turner, David D. (12 June 2024). "The Propagation, Evolution, and Rotation in Linear Storms (PERiLS) Project". Bulletin of the American Meteorological Society. -1 (aop). American Meteorological Society. doi:10.1175/BAMS-D-22-0064.1.
^"HGX Tornado Warning #8". mesonet.agron.iastate.edu. National Weather Service Houston/Galveston TX. Archived from the original on 1 September 2020. Retrieved 24 January 2023.
^Pieter Groenemeijer (ESSL); Lothar Bock (DWD); Juan de Dios Soriano (AEMet); Maciej Dutkiewicz (Bydgoszcz University of Science and Technology); Delia Gutiérrez-Rubio (AEMet); Alois M. Holzer (ESSL); Martin Hubrig; Rainer Kaltenberger; Thilo Kühne (ESSL); Mortimer Müller (Universität für Bodenkultur); Bas van der Ploeg; Tomáš Púčik (ESSL); Thomas Schreiner (ESSL); Miroslav Šinger (SHMI); Gabriel Strommer (ESSL); Andi Xhelaj (University of Genova) (30 July 2023). "The International Fujita (IF) Scale"(PDF). European Severe Storms Laboratory. Retrieved 30 July 2023.
^Kosiba, Karen (28 April 2024). "@DOWFacility research RE many peoples' questions"(Post on 𝕏). 𝕏 (Formerly Twitter). @karen_kosiba. Retrieved 29 April 2024. These data: Height ~258 m ARL (see 2) Gate 12m/beam 122m, gusts ~1sec