Process-based flood frequency analysis in an agricultural watershed exhibiting nonstationary flood seasonality

Floods are the product of complex interactions among processes including precipitation, soil moisture, and watershed morphology. Conventional flood frequency analysis (FFA) methods such as design storms and discharge-based statistical methods offer few insights into these process interactions and ho...

Full description

Saved in:
Bibliographic Details
Published in:Hydrology and earth system sciences 2019-05, Vol.23 (5), p.2225-2243
Main Authors: Yu, Guo, Wright, Daniel B., Zhu, Zhihua, Smith, Cassia, Holman, Kathleen D.
Format: Article
Language:English
Subjects:
Agricultural watersheds
Climate change
Computer simulation
Design storms
Extreme weather
Flood control
Flood frequency
Flood frequency analysis
Floods
Frequency analysis
Hydroclimate
Hydrologic models
Hydrologic processes
Hydrology
Interactions
Land use
Morphology
Precipitation
Probability theory
Rain
Rainfall
Records
Remote sensing
River discharge
Rivers
Seasonal variations
Seasonality
Soil
Soil moisture
Statistical analysis
Statistical methods
Stochasticity
Storms
Transposition
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Floods are the product of complex interactions among processes including precipitation, soil moisture, and watershed morphology. Conventional flood frequency analysis (FFA) methods such as design storms and discharge-based statistical methods offer few insights into these process interactions and how they “shape” the probability distributions of floods. Understanding and projecting flood frequency in conditions of nonstationary hydroclimate and land use require deeper understanding of these processes, some or all of which may be changing in ways that will be undersampled in observational records. This study presents an alternative “process-based” FFA approach that uses stochastic storm transposition to generate large numbers of realistic rainstorm “scenarios” based on relatively short rainfall remote sensing records. Long-term continuous hydrologic model simulations are used to derive seasonally varying distributions of watershed antecedent conditions. We couple rainstorm scenarios with seasonally appropriate antecedent conditions to simulate flood frequency. The methodology is applied to the 4002 km2 Turkey River watershed in the Midwestern United States, which is undergoing significant climatic and hydrologic change. We show that, using only 15 years of rainfall records, our methodology can produce accurate estimates of “present-day” flood frequency. We found that shifts in the seasonality of soil moisture, snow, and extreme rainfall in the Turkey River exert important controls on flood frequency. We also demonstrate that process-based techniques may be prone to errors due to inadequate representation of specific seasonal processes within hydrologic models. If such mistakes are avoided, however, process-based approaches can provide a useful pathway toward understanding current and future flood frequency in nonstationary conditions and thus be valuable for supplementing existing FFA practices.
ISSN:1607-7938
1027-5606
1607-7938
DOI:10.5194/hess-23-2225-2019