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<br />Erosion <br /> <br />Several researchers[8-11] have shown that erosion of saline shales and dissolution of <br />efflorescence (surface salts) increase salinity during thunderstorms. Low elevation <br />snowmelt on saline geologic formations may also contribute significantly to salinity. <br />Analyses of the Green River near the Green River, Utah, station indicate that salinity <br />remains unusually high during peak flows associated with snowmelt runoff events. <br /> <br />Reclamation studies on the McElmo Creek Salinity Control Unit found that approxi- <br />mately 32 percent of the total salt load could be related to runoff events. Other <br />studies by Reclamation show that 21 percent of the Price River salt load and <br />14 percent of the San Rafael River salt load are related to natural runoff events. <br /> <br />Studies[12] conducted on Mancos Shale in the Upper Colorado River Basin have <br />demonstrated a positive relationship between sediment yield and salt production. <br />Sediment yield increases as a result of either upland erosion or streambank and gully <br />erosion. Upland erosion is attributed to rill and inter-rill flow. Salt and sediment <br />yields are dependent upon storm period, landform type, and the soluble mineral <br />content of the geologic formation. <br /> <br />Studies[13] conducted in the Price River Basin have demonstrated that the highest <br />salt and sediment concentrations occur in the first streamflow event following a long <br />period of no discharge. The accumulation of salts in the channel is attributed to <br />efflorescence resulting from the drying of the channel. Salt yields occurring after the <br />initial flushing of the channel are similar to those found in the surrounding watershed <br />soils. <br /> <br />Sediment and the resulting salt yield are highly dependent upon landform type. Three <br />major landform types-badlands, pediments, and alluvial valleys-are associated with <br />the Mancos Shale terrain. <br /> <br />Badlands are the most erosionally unstable, with sediment yields as high as 15 tons <br />per acre [14]. Rilling accounts for approximately 80 percent of the erosion [13] . <br />Because salt production is closely related to sediment yield and the badland soils have <br />not been leached of their soluble minerals, they produce the greatest amount of salt of <br />the landform types. <br /> <br />Pediments are gently inclined planate erosion surfaces carved in bedrock and <br />generally veneered with fluvial gravels. The surface slopes of pediments are gentle, <br />making them relatively stable. Pediments have deeper soils and higher infiltration <br />rates than badlands; thus, they support a greater vegetation cover and are less <br />erOSIve. <br /> <br />Alluvial valleys are formed by a change in gradient and the deposition of sediment. <br />They are stable except along the channel where headcutting and gullying occur. Most <br />of the salts have been leached from the alluvial deposits; thus, erosion of their <br />landform type yields less salts per unit volume of sediment than the other two <br />landform types. However, channels incised into alluvium incorporate both sediment <br />and salt from sloughed channel banks and salts from efflorescence at the <br />alluvium-bedrock contacts[12]. <br /> <br />I <br /> <br />13 <br />