Tornado outbreak of April 2–3, 1956

1956 windstorm in the central United States

From April 2–3, 1956, a large, deadly tornado outbreak affected the Great Plains, parts of the South, and the upper Midwest in the contiguous United States, especially the Great Lakes region. The outbreak produced at least 55 tornadoes, including an F5 that devastated the Grand Rapids metropolitan area in the U.S. state of Michigan on April 3. It was one of three tornadoes to move across southwest Lower Michigan on that day. A fourth tornado struck north of the Manistee area, in the northern part of the peninsula. The Hudsonville–Standale tornado killed 18 and injured 333. It remains the fourth deadliest tornado on record in Michigan and is the most recent F5 on record there. Several other deadly, intense, long-tracked tornadoes also occurred during the outbreak. In addition to the fatalities in Kansas, Oklahoma, Michigan and Berlin, Wisconsin, three people were killed in Tennessee, one person in Kentucky and two more people in Wisconsin. In total, 39 were killed during the entire event.^{[nb 1]}

Background

Tuesday, April 3, 1956, was a warm and humid day across most of the Midwestern U.S., the Great Lakes and the Ohio Valley. Temperatures in the areas affected by the worst of the outbreak were well into the 70s °F, approaching 80 °F (27 °C) in Michigan, with anomalously high dew points—the latter exceeding 60 °F (16 °C) near the shoreline of Lake Michigan. A potent low-pressure area accompanied an intense mid-latitude cyclone with a pronounced dry line located near the western Great Lakes. An attendant warm front extended eastward over Wisconsin, a vigorous cold front southward through Illinois. In tandem with the advancing trough, a strong jet stream with winds up to 135 kn (155 mph; 250 km/h) extended over Little Rock, Arkansas, and impinged on the Upper Midwest. Prior to the arrival of the storms in the region, schools had closed earlier than usual due to the threat of severe weather. By late afternoon, the cold front crossed over the western Great Lakes including Lake Michigan.^[2]

Outbreak statistics

Confirmed tornadoes

Prior to 1990, there is a likely undercount of tornadoes, particularly E/F0–1, with reports of weaker tornadoes becoming more common as population increased. A sharp increase in the annual average E/F0–1 count by approximately 200 tornadoes was noted upon the implementation of NEXRAD Doppler weather radar in 1990–1991.^{[10][nb 5]} 1974 marked the first year where significant tornado (E/F2+) counts became homogenous with contemporary values, attributed to the consistent implementation of Fujita scale assessments.^{[14][nb 3]} Numerous discrepancies on the details of tornadoes in this outbreak exist between sources. The total count of tornadoes and ratings differs from various agencies accordingly. The list below documents information from the most contemporary official sources alongside assessments from tornado historian Thomas P. Grazulis.

• In addition to confirmed tornadoes, a funnel cloud near Jenera, Ohio, was officially but incorrectly listed as a tornado.^[15][16]

Saugatuck–Gibson–Graafschap–Holland, Michigan

This violent tornado was the first member of a long-lived, destructive family. It and the Hudsonville–Standale F5 are officially listed as a single, long-tracked, continuous tornado with a 58.8-mile-long (94.6 km) path, but were retrospectively and separately determined by Thomas P. Grazulis and the National Weather Service to have been a family of two or more tornadoes, one of which was a 9-mile-long (14 km) F4 (possibly an F5 as well) and the other a 48-mile-long (77 km) F5, the latter being the most recent F5 tornado on record in the U.S. state of Michigan. The first tornado may have passed through or near Gibson and Graafschap, lifted near Holland, and passed aloft over Zeeland Charter Township before reforming into and touching down as a second tornado just east of town. This second tornado then continued northeast before lifting a short distance north of Trufant.

The first member of the family developed over Lake Michigan and moved ashore a short distance south of Oval Beach, damaging a CBU building and several summer houses at Camp Gray. Heading north-northeastward, it passed near Mount Baldhead, wrecking a wooden beachfront home. An old, well-constructed, anchor-bolted lighthouse, fastened by a dozen iron pylons, was leveled, along with a trio of outbuildings and a cabin; all the pylons at the lighthouse were snapped or dislodged, indicating F4 winds. The tornado crossed part of the present-day Saugatuck Dunes State Park. Along the rest of its path, the tornado wrecked three homes—one brick, a pair frame, a twin-storied among the latter—and unroofed or destroyed a few barns. A few of the homes sustained at least F4 damage. Windows were smashed at a multi-story retail structure as well. Barns, outbuildings, and garages were wrecked along the path. Seven people were injured.^[114]

Vriesland–Hudsonville–Standale–Comstock Park–Trufant, Michigan

Beginning a short distance east of Vriesland in Ottawa County, Michigan, this extremely violent tornado formed shortly after the dissipation of the Saugatuck F4. Rapidly intensifying, it moved northeastward over the southwestern and northern suburbs of Grand Rapids, causing F5 damage to businesses and homes there. Within half an hour the tornado killed 13 people as it tracked from Hudsonville to Standale and thence to Comstock Park, the last of which would be hit by an F4 tornado on Palm Sunday in 1965. Homes in Hudsonville and Standale were cleanly swept away from their foundations, with only small pieces of debris recovered in some locations. At least one home was so obliterated that all the floor tiles had been completely scoured from the foundation. Vehicles nearby were tossed hundreds of yards and mangled beyond recognition. Extensive wind-rowing of debris was observed, and hundreds of trees were snapped and debarked as well. After devastating the Hudsonville–Standale area, the tornado continued northeastward, past Rockford, obliterating a home, destroying a mobile home park, and damaging several farmsteads before dissipating. 18 people were killed and 333 others were injured by the storm. This, the fourth deadliest tornado in Michigan on record, was the last F5 (confirmed and/or possible) in the U.S. state of Michigan and occurred three years after the Flint–Beecher tornado that killed 116. The tornado that struck the Grand Rapids area was the inspiration for the La Dispute song "Hudsonville, MI 1956". Meanwhile, Hudsonville would be hit directly by a brief-but-strong F2 tornado just one year later, although that tornado caused no casualties.^[115]

Bangor–Allegan–Lowell, Michigan

This intense, long-lived tornado family passed through or near Bangor, Bloomingdale, and the southern half of Allegan. Near the Van Buren–Allegan County line, it leveled a farmhouse and swept away several lakeside cabins; the farmhouse may have sustained F4 damage, but may not have been sufficiently well built, so only F3 damage is confirmable. In Allegan, the tornado mostly unroofed a road commission building and a factory, and 12 or more farms reported severe losses to livestock. Afterward, the tornado weakened, veered rightward, and may have lifted and reformed into a new event, as no structural damage occurred and damage to vegetation was lighter than elsewhere along the path. The tornado then re-intensified in Barry and Kent counties, badly damaging many farms. In all, the tornado destroyed 29 homes, mostly at low-end F3 intensity. A dozen people were injured.^[116]

See also

• List of North American tornadoes and tornado outbreaks
• List of F5 and EF5 tornadoes
• 1920 Palm Sunday tornado outbreak — Also produced multiple violent tornadoes in Michigan
• 2011 Joplin tornado — Also affected the Joplin metropolitan area

Notes

1. An outbreak is generally defined as a group of at least six tornadoes (the number sometimes varies slightly according to local climatology) with no more than a six-hour gap between individual tornadoes. An outbreak sequence, prior to (after) the start of modern records in 1950, is defined as a period of no more than two (one) consecutive days without at least one significant (F2 or stronger) tornado.^[1]
2. All dates are based on the local time zone where the tornado touched down; however, all times are in Coordinated Universal Time and dates are split at midnight CST/CDT for consistency.
3. The Fujita scale was devised under the aegis of scientist T. Theodore Fujita in the early 1970s. Prior to the advent of the scale in 1971, tornadoes in the United States were officially unrated.^[3][4] Tornado ratings were retroactively applied to events prior to the formal adoption of the F-scale by the National Weather Service.^[5] While the Fujita scale has been superseded by the Enhanced Fujita scale in the U.S. since February 1, 2007,^[6] Canada used the old scale until April 1, 2013;^[7] nations elsewhere, like the United Kingdom, apply other classifications such as the TORRO scale.^[8]
4. The National Oceanic and Atmospheric Administration's Storm Data publication does not list exact damage totals for every event, instead giving damage categories. As such, damage for individual tornadoes is not comprehensive.^[9]
5. Historically, the number of tornadoes globally and in the United States was and is likely underrepresented: research by Grazulis on annual tornado activity suggests that, as of 2001, only 53% of yearly U.S. tornadoes were officially recorded. Documentation of tornadoes outside the United States was historically less exhaustive, owing to the lack of monitors in many nations and, in some cases, to internal political controls on public information.^[11] Most countries only recorded tornadoes that produced severe damage or loss of life.^[12] Significant low biases in U.S. tornado counts likely occurred through the early 1990s, when advanced NEXRAD was first installed and the National Weather Service began comprehensively verifying tornado occurrences.^[13]
6. All starting coordinates are based on the NCEI database and may not reflect contemporary analyses
7. The listed width values are primarily the average/mean width of the tornadoes, with those having known maximum widths denoted by ♯. From 1952 to 1994, reports largely list mean width whereas contemporary years list maximum width.^[17] Values provided by Grazulis are the average width, with estimates being rounded down (i.e. 0.5 mi (0.80 km) is rounded down from 880 yards to 800 yards.^[18][19]

References

1. Schneider, Russell S.; Brooks, Harold E.; Schaefer, Joseph T. (2004). Tornado Outbreak Day Sequences: Historic Events and Climatology (1875–2003) (PDF). 22nd Conf. Severe Local Storms. Hyannis, Massachusetts: American Meteorological Society. Retrieved September 17, 2019.
2. Multiple sources:
   • "1956 Tornado Outbreak Overview". Grand Rapids, MI Weather Forecast Office. Grand Rapids, Michigan: National Weather Service. Retrieved 7 June 2020.
   • "Hudsonville-Standale tornado". WOOD-TV. Grand Rapids, Michigan: WorldNow. 3 April 2006. Archived from the original on 9 September 2007. Retrieved 7 June 2020.
   • Ostuno 2008, pp. 8–9
3. Grazulis 1993, p. 141.
4. Grazulis 2001a, p. 131.
5. Edwards et al. 2013, p. 641–642.
6. Edwards, Roger (March 5, 2015). "Enhanced F Scale for Tornado Damage". The Online Tornado FAQ (by Roger Edwards, SPC). Storm Prediction Center. Retrieved February 25, 2016.
7. "Enhanced Fujita Scale (EF-Scale)". Environment and Climate Change Canada. Environment and Climate Change Canada. June 6, 2013. Archived from the original on March 3, 2016. Retrieved February 25, 2016.
8. "The International Tornado Intensity Scale". Tornado and Storm Research Organisation. Tornado and Storm Research Organisation. 2016. Archived from the original on March 5, 2016. Retrieved February 25, 2016.
9. Storm Data Publication 1956, Events reported
10. Agee and Childs 2014, p. 1496.
11. Grazulis 2001a, pp. 251–4.
12. Edwards, Roger (March 5, 2015). "The Online Tornado FAQ (by Roger Edwards, SPC)". Storm Prediction Center: Frequently Asked Questions about Tornadoes. Storm Prediction Center. Retrieved February 25, 2016.
13. Cook & Schaefer 2008, p. 3135.
14. Agee and Childs 2014, pp. 1497, 1503.
15. Storm Data Publication 1956, #10083356
16. USWB 1956, p. 114.
17. Agee and Childs 2014, p. 1494.
18. Brooks 2004, p. 310.
19. Grazulis 1990, p. ix.
20. USWB 1956, p. 106.
21. Storm Data Publication 1956, #10063704
22. Storm Data Publication 1956, #10007475
23. Storm Data Publication 1956, #10092621
24. USWB 1956, p. 107.
25. Storm Data Publication 1956, #10025422
26. Grazulis 1993, p. 993.
27. Storm Data Publication 1956, #10025425
28. Storm Data Publication 1956, #10025434
29. Storm Data Publication 1956, #10025435
30. Storm Data Publication 1956, #10025436
31. Storm Data Publication 1956, #10092622
32. Storm Data Publication 1956, #10092623
33. USWB 1956, p. 108.
34. Storm Data Publication 1956, #10025427
35. "Severe Weather Database Files (1950-2021)". Storm Prediction Center Maps, Graphics, and Data Page. Norman, Oklahoma: Storm Prediction Center. July 11, 2021. Retrieved 24 February 2022.
36. Storm Data Publication 1956, #10025429
37. Storm Data Publication 1956, #10092624
38. Storm Data Publication 1956, #10092625
39. Storm Data Publication 1956, #10092627
40. Storm Data Publication 1956, #10092628
41. Storm Data Publication 1956, #10092629
42. Storm Data Publication 1956, #10092632
43. Grazulis 1984, p. A-65.
44. Storm Data Publication 1956, #10092630
45. Storm Data Publication 1956, #10025440
46. Storm Data Publication 1956, #10025445
47. Storm Data Publication 1956, #10025447
48. USWB 1956, pp. 108–9.
49. Storm Data Publication 1956, #10025437
50. Storm Data Publication 1956, #10025441
51. Storm Data Publication 1956, #10025444
52. USWB 1956, p. 109.
53. Storm Data Publication 1956, #10092631
54. Storm Data Publication 1956, #10093492
55. Storm Data Publication 1956, #10093493
56. Storm Data Publication 1956, #10093494
57. USWB 1956, pp. 109–10.
58. Storm Data Publication 1956, #10025446
59. Storm Data Publication 1956, #10025449
60. Storm Data Publication 1956, #10025453
61. Storm Data Publication 1956, #10069400
62. Storm Data Publication 1956, #10025451
63. Storm Data Publication 1956, #10025452
64. Storm Data Publication 1956, #10025455
65. Storm Data Publication 1956, #10025457
66. Storm Data Publication 1956, #10025456
67. Storm Data Publication 1956, #10093496
68. USWB 1956, p. 110.
69. Storm Data Publication 1956, #10093497
70. Storm Data Publication 1956, #10025458
71. Storm Data Publication 1956, #10025459
72. Storm Data Publication 1956, #10063708
73. USWB 1956, pp. 110–1.
74. Storm Data Publication 1956, #10063707
75. USWB 1956, p. 111.
76. Grazulis 1993, p. 994.
77. Storm Data Publication 1956, #10147919
78. Storm Data Publication 1956, #9983100
79. Storm Data Publication 1956, #10147920
80. Storm Data Publication 1956, #9983101
81. Grazulis 1984, p. A-66.
82. Storm Data Publication 1956, #10147921
83. Storm Data Publication 1956, #10147922
84. USWB 1956, p. 112.
85. Grazulis 1993, pp. 994–5.
86. Storm Data Publication 1956, #10049838
87. Storm Data Publication 1956, #10007476
88. Storm Data Publication 1956, #10007478
89. Storm Data Publication 1956, #10037016
90. Storm Data Publication 1956, #10037017
91. Storm Data Publication 1956, #10005193
92. USWB 1956, pp. 112, 126.
93. Storm Data Publication 1956, #10007479
94. Grazulis 1993, p. 995.
95. Storm Data Publication 1956, #10127395
96. Storm Data Publication 1956, #10005194
97. USWB 1956, p. 113.
98. Storm Data Publication 1956, #10007480
99. Storm Data Publication 1956, #10005195
100. Storm Data Publication 1956, #10037018
101. Ostuno 2008, pp. 3, 13–4, 16.
102. Storm Data Publication 1956, #10040544
103. Storm Data Publication 1956, #10040546
104. Storm Data Publication 1956, #10040549
105. Storm Data Publication 1956, #10049839
106. Storm Data Publication 1956, #10049840
107. Storm Data Publication 1956, #10127396
108. Storm Data Publication 1956, #10005198
109. Storm Data Publication 1956, #10049841
110. Storm Data Publication 1956, #10005196
111. Storm Data Publication 1956, #10005197
112. Storm Data Publication 1956, #10005199
113. Storm Data Publication 1956, #10049839
114. Multiple sources:
     • Grazulis 1993, p. 995
     • Grazulis 2001b, p. 22
     • Hayden, Jim (3 April 2006). "Five decades ago, titanic tornado took out century-old lighthouse". The Holland Sentinel. Holland, Michigan: Gatehouse Media. Archived from the original on 4 April 2009. Retrieved 7 June 2020.
     • Ostuno 2008, pp. 11–2, 15–6
     • Storm Data Publication 1956, #10040545
     • "The Saugatuck to Holland Tornado". Grand Rapids, MI Weather Forecast Office. Grand Rapids, Michigan: National Weather Service. 2 August 2007. Retrieved 20 September 2023.
     • "Vriesland to Trufant". Grand Rapids, MI Weather Forecast Office. Grand Rapids, Michigan: National Weather Service. 28 September 2009. Retrieved 20 September 2023.
     • USWB 1956, p. 113
115. Multiple sources:
     • Edwards, Roger, ed. (March 19, 2021). "F5 and EF5 Tornadoes of the United States, 1950-present". The Online Tornado FAQ: Frequently Asked Questions about Tornadoes. Norman, Oklahoma: Storm Prediction Center. Retrieved 3 February 2022.
     • Grazulis 1993, p. 995
     • Grazulis 2001b, p. 22
     • Grazulis, Thomas P.; Grazulis, Doris (26 April 2000). "The Most "Important" US Tornadoes by State". The Tornado Project Online. The Tornado Project. Archived from the original on 2016-03-04. Retrieved 2 March 2016.
     • Hayden, Jim (3 April 2006). "Five decades ago, titanic tornado took out century-old lighthouse". The Holland Sentinel. Holland, Michigan: Gatehouse Media. Archived from the original on 4 April 2009. Retrieved 7 June 2020.
     • Ostuno 2008, pp. 2, 12–3, 16
     • Storm Data Publication 1956, #10040547
     • Storm Data Publication 1956, #10040550
     • Storm Data Publication 1956, #10040553
     • "The Saugatuck to Holland Tornado". Grand Rapids, MI Weather Forecast Office. Grand Rapids, Michigan: National Weather Service. 2 August 2007. Retrieved 20 September 2023.
     • "Vriesland to Trufant". Grand Rapids, MI Weather Forecast Office. Grand Rapids, Michigan: National Weather Service. 28 September 2009. Retrieved 20 September 2023.
     • USWB 1956, p. 113
116. Multiple sources:
     • "Bangor to Lowell". Grand Rapids, MI Weather Forecast Office. Grand Rapids, Michigan: National Weather Service. Retrieved 7 October 2023.
     • Grazulis 1993, p. 995
     • Ostuno 2008, pp. 3, 14, 16
     • Storm Data Publication 1956, #10040548
     • Storm Data Publication 1956, #10040551
     • Storm Data Publication 1956, #10040552
     • USWB 1956, p. 113

Sources

• Agee, Ernest M.; Childs, Samuel (June 1, 2014). "Adjustments in Tornado Counts, F-Scale Intensity, and Path Width for Assessing Significant Tornado Destruction". Journal of Applied Meteorology and Climatology. 53 (6). American Meteorological Society: 1494–1505. doi:10.1175/JAMC-D-13-0235.1.
• Brooks, Harold E. (April 2004). "On the Relationship of Tornado Path Length and Width to Intensity". Weather and Forecasting. 19 (2): 310–19. Bibcode:2004WtFor..19..310B. doi:10.1175/1520-0434(2004)019<0310:OTROTP>2.0.CO;2.
• Cook, A. R.; Schaefer, J. T. (August 2008). "The Relation of El Niño–Southern Oscillation (ENSO) to Winter Tornado Outbreaks". Monthly Weather Review. 136 (8): 3121–3137. Bibcode:2008MWRv..136.3121C. doi:10.1175/2007MWR2171.1.
• Edwards, Roger; LaDue, James G.; Ferree, John T.; Scharfenberg, Kevin; Maier, Chris; Coulbourne, William L. (May 1, 2013). "Tornado Intensity Estimation: Past, Present, and Future". Bulletin of the American Meteorological Society. 94 (5). American Meteorological Society: 641–653. doi:10.1175/BAMS-D-11-00006.1.
• Grazulis, Thomas P. (May 1984). Violent Tornado Climatography, 1880–1982. OSTI (Technical report). NUREG. Washington, D.C.: Nuclear Regulatory Commission. OSTI 7099491. CR-3670.
  • — (November 1990). Significant Tornadoes 1880–1989. Vol. 2. St. Johnsbury, Vermont: The Tornado Project of Environmental Films. ISBN 1-879362-02-3.
  • — (July 1993). Significant Tornadoes 1680–1991: A Chronology and Analysis of Events. St. Johnsbury, Vermont: The Tornado Project of Environmental Films. ISBN 1-879362-03-1.
  • — (2001a). The Tornado: Nature's Ultimate Windstorm. Norman: University of Oklahoma Press. ISBN 978-0-8061-3538-0.
  • — (2001b). F5-F6 Tornadoes. St. Johnsbury, Vermont: The Tornado Project of Environmental Films.
• National Weather Service (April 1956). Storm Data Publication (Report). National Centers for Environmental Information – via Storm Events Database.
• Ostuno, E. J. (2008). Written at Grand Rapids, Michigan. Roger Edwards (ed.). "A Case Study in Forensic Meteorology: Investigating the 3 April 1956 Tornadoes in Western Lower Michigan". e-Journal of Severe Storms Meteorology. 3 (1). Norman, Oklahoma: 1–33. doi:10.55599/ejssm.v3i1.14. S2CID 109690212. Retrieved 7 June 2020.
• U.S. Weather Bureau (April 1956). "Storm data and unusual weather phenomena". Climatological Data National Summary. 7 (4). Asheville, North Carolina: National Climatic Data Center: 106–14.