4.7 Article

THE GREAT COLORADO FLOOD OF SEPTEMBER 2013

Journal

BULLETIN OF THE AMERICAN METEOROLOGICAL SOCIETY
Volume 96, Issue 9, Pages 1461-1487

Publisher

AMER METEOROLOGICAL SOC
DOI: 10.1175/BAMS-D-13-00241.1

Keywords

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Funding

  1. National Science Foundation [AGS-1157425]
  2. U.S. National Science Foundation through NCAR
  3. Direct For Computer & Info Scie & Enginr
  4. Office of Advanced Cyberinfrastructure (OAC) [1234742] Funding Source: National Science Foundation
  5. Direct For Mathematical & Physical Scien
  6. Division Of Mathematical Sciences [1107046] Funding Source: National Science Foundation
  7. Directorate For Geosciences
  8. Div Atmospheric & Geospace Sciences [1157425] Funding Source: National Science Foundation

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During the second week of September 2013, a seasonally uncharacteristic weather pattern stalled over the Rocky Mountain Front Range region of northern Colorado bringing with it copious amounts of moisture from the Gulf of Mexico, Caribbean Sea, and the tropical eastern Pacific Ocean. This feed of moisture was funneled toward the east-facing mountain slopes through a series of mesoscale circulation features, resulting in several days of unusually widespread heavy rainfall over steep mountainous terrain. Catastrophic flooding ensued within several Front Range river systems that washed away highways, destroyed towns, isolated communities, necessitated days of airborne evacuations, and resulted in eight fatalities. The impacts from heavy rainfall and flooding were felt over a broad region of northern Colorado leading to 18 counties being designated as federal disaster areas and resulting in damages exceeding $2 billion (U.S. dollars). This study explores the meteorological and hydrological ingredients that led to this extreme event. After providing a basic timeline of events, synoptic and mesoscale circulation features of the event are discussed. Particular focus is placed on documenting how circulation features, embedded within the larger synoptic flow, served to funnel moist inflow into the mountain front driving several days of sustained orographic precipitation. Operational and research networks of polarimetric radar and surface instrumentation were used to evaluate the cloud structures and dominant hydrometeor characteristics. The performance of several quantitative precipitation estimates, quantitative precipitation forecasts, and hydrological forecast products are also analyzed with the intention of identifying what monitoring and prediction tools worked and where further improvements are needed.

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