Rivers and Floods Assignment(1)

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University of Arkansas *

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Geography

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Feb 20, 2024

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LAB 7: RIVERS, FLOODS & RIPARIAN ZONES 100 points Due at the beginning of the next lab. LEARNING OUTCOMES At the end of this lab, you will be able to 1. Construct a flood frequency curve (hydrograph) 2. Understand and interpret a hydrograph 3. Predict the probability of a flood of a certain discharge along a stream INTRODUCTION Streams and rivers perform an essential function of runoff integration within a watershed to efficiently remove the water from the drainage basin. Basic components of a stream shown in Figure 1 include the streambed, banks, and levees, which define the active channel and the associated floodplain. Just as the name implies, the floodplain performs a specific essential function by providing space for temporary storage of water during times of excess discharge. Thus, by its very nature and function we know that this area will be periodically under water (flooded). Because we occupy and utilize the floodplain for homes, businesses, and transportation networks, it is important that we understand how to predict the frequency and magnitude of floods. This allows us to minimize resulting loss of life and damage to property. At least 1,850 people died in twenty-four separate riverine and flash floods in the United States during the 20 th century. If ice-jam, storm-surge, dam-failure, and mudflow floods are included this number jumps to over 9,000 during this period. Dollar losses associated with floods are in the billions. Riverine and flash floods are controlled by 1) the amount, timing, type, and distribution of precipitation, and 2) the topographic and geologic character of the drainage basin. Large riverine floods usually involve rapid snow melt or excessive rainfall over the drainage basin. These floods tend to inundate large areas and are of relatively long duration (days, weeks or even months). In contrast, flash floods often result from high intensity precipitation in small watersheds, often in areas of moderate to high topographic relief. These floods tend to impact smaller areas than the riverine floods and are of shorter duration (hours to days). However, flash floods often result in more deaths that the longer lasting riverine floods. To understand flood frequency and magnitude we must first acquire a basic grasp of terminology. One of the components used to describe stream flow is the hydrograph. The hydrograph is an x-y plot of discharge or stage vs. time. See Figure 2 in question 1 for an example. Stream Discharge is the volume of water passing a specific point along the stream over a specific time interval. Discharge is therefore length cubed (L 3 ) divided by time (t) or L 3 /t. You will 1

often see these units expressed as cubic feet per second (cfs or ft 3 /s) or cubic meters per second (m 3 /s) or gallons per minute (gpm). Discharge is calculated as the wetted cross-sectional area of flow times the velocity using the following formula: Q = A * V Q = discharge (L 3 /t) = (Length 3 /time) A = cross-sectional area = depth (d) x width (w) = Length 2 (L 2 ) V = velocity (L/t) = Length/time The frequency of annual peak flows (flood frequency) is expressed as a recurrence interval. The recurrence interval is the average time interval between the occurrence of two similar peak flows and is calculated as: T = (n+1)/m T = recurrence interval in years n = number of years of record m = rank or order from greatest (1) to smallest Recurrence interval can be plotted on semi-log graph paper with the recurrence interval on the x-axis (the log axis) and discharge or stage plotted on the y-axis (arithmetic axis). Connecting the points on the plot with a “best fit” line provides a mechanism to estimate the recurrence interval of peak flows other than those for which data are available. Another term one often encounters is the annual probability of exceedance which is the reciprocal of T. P = 1/T P = probability of exceedance T = recurrence interval in years This is the probability that each year the annual maximum discharge will be met or exceeded for any given discharge. An annual peak discharge with recurrence interval of 100 years has a 1 percent chance of occurring in any year. LAB 7: FLOODING AND RIVERS Name: _____________________________ Section: _____________________________ Answer the following questions [100 pts]. 2

Figure 1. Hydrograph showing predicted and actual streamflow in response to a storm. Hydrograph Interpretation 1. Based on the hydrograph above, what is the lag time between the start of the rain and the peak river stage? (5 points) 2. At peak river stage how many feet were each of the forecasts off by? Why might the forecasts be inaccurate? (5 points) 3

3. If urbanization occurred in this watershed, would the hydrograph have a higher or lower peak? Will flash floods be more or less likely? (5 points) Figure 2. Hydrograph showing Discharge vs. Time for Illinois River south of Siloam Springs, AR. Q = A * V Q = discharge (ft 3 /s) A = cross-sectional area (ft 2 ) = depth (ft) x width (ft) V = velocity (ft/s) 4. Based on the figure and the equation above, calculate the width of the stream at point A assuming an instantaneous velocity of 4 ft/s and a stream depth of 2.4 ft. (Show all work and include units) (5 points) 4

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