The upper watershed (upstream of
Electron) of the Puyallup River was created by the advance of alpine glaciers on
Mount Rainier, limiting its maximum possible age to approximately 500,000 years when
Mount Rainier was first formed. It is characterized by deep glacial valleys carved through the low mountains and rugged foothills of Washington's South
Cascade Range. The lower watershed (downstream of
Electron) is much younger than the upper watershed: a combination of glacial and tectonic features less than 20,000 years old as well as changes caused by the
Osceola Mudflow and younger
lahars between 5,600 years
Before Present and today. The main valley was originally part of a much larger lateral
meltwater channel network formed during the
Vashon Glaciation, which drained large portions of the Puget Sound Area as well as most of Washington's
Cascade Range south into the Chehalis River prior to the unblocking of the
Strait of Juan de Fuca around 14,800 years
Before Present. After the retreat of the
Cordilleran Ice Sheet allowed
Puget Sound to connect with the
Pacific Ocean through the Strait, the channel network fragmented into a collection of large, independent river valleys draining into
Puget Sound. The Puyallup River's portion consisted of small section of lateral meltwater channel between Lake Kapowsin and Orting, a primary subglacial channel running north from
Orting through the Duwamish Valley to
Lake Washington, and a channel fork which split off at
Sumner to follow a
tectonic fault associated with the
Tacoma Fault Zone. As both sea level and land level recovered from the glaciation, the valley flooded and became a saltwater embayment of Puget Sound which extended through the Puyallup and Duwamish Valleys from
Kenmore, Washington, on what is now
Lake Washington, to
Orting at the foothills of the
Cascade Range. Sediment from the Puyallup River,
Carbon River, and
White River steadily built up in the valley through the early Holocene, and by approximately 5,700 years
Before Present the valley was filled in to
Sumner, separating the Duwamish Valley from the fork running west-northwest to
Tacoma. The Puyallup River split, emptying into Puget Sound to both the north and the west. Starting around 5,600 years
Before Present and continuing to 800 years
Before Present, a series of large
mudslides from
Mount Rainier flowed down the Puyallup River and White River watersheds and filled in the Puyallup and Duwamish Valleys, creating the present landscape. Today, the Puyallup River and its tributaries are still fed by the glaciers of
Mount Rainier. These glaciers continually provide
sediment such as silt and gravel to the rivers, creating sand and gravel bars. The thick sediment deposits in the
stream beds lower water capacity, which causes the river to meander and flood during periods of high streamflow. It also causes the rivers to become
braided and
meandering. During the summer, glacial meltwater dominates the streamflow, turning the Puyallup River
turbid. In addition, the glaciers delay the onset of spring-summer
runoff, compared to unglaciated river basins. Historically, these factors resulted in frequent flooding and extensive floodplain
wetlands, and provided a rich and complex habitat for fish and other animals. In addition, the river's mouth at Commencement Bay occupied an extensive tidal flat and wetland
estuary delta.
Urbanization and an extensive system of flood control structures such as dams, levees, and culverts, have radically altered much of the Puyallup River and its tributaries. The estuary delta at the mouth of the Puyallup River has been almost completely replaced with the facilities of the Port of Tacoma, with less than 5% of the original estuarine habitat remaining. A fall run of
chinook salmon occurs on the river.
coho,
chum, and
pink salmon are also found in the river, along with
steelhead, sea-run
coastal cutthroat trout, and a threatened species,
bull trout.
Sockeye salmon are considered indigenous to the basin, but are rarely seen today. ==River modifications==