CwM recently began working with a small rural wastewater Special District located in central Lane County after successfully developing a $100,000 grant application to support the District. The funding is part of Representative Cedric Hayden’s Rural Infrastructure Special District Grant, which in turn is related to the national Infrastructure Investment and Jobs Act (IIJA). The District and its wastewater treatment facility have been in operation since the early 1980s and currently serve about 700 residents. The treatment facility utilizes a large drainfield, originally constructed under an EPA grant, to dispose of treated effluent to the subsurface. The District is currently in need of a new Water Pollution Control Facility (WPCF) permit to regulate and manage its continued operations. CwM is assisting in the process of obtaining a new WPCF permit by characterizing hydrogeologic conditions at the drainfield site and monitoring shallow groundwater.

CwM staff took the Sanitary District site visit as an opportunity to to some exploring in the upper Willamette River watershed. The District’s treatment facility is located below the Dexter Lake Dam. Dexter Lake is the lower of two adjacent dammed lakes on the Middle Fork of the Willamette River, the other being Lookout Point Lake and Dam. The lakes were constructed in 1953-1954 by the US Army Corps of Engineers. The beautiful lakes and surrounding parks provide many opportunities for fishing, boating, rowing, horseback riding, and biking. The two dams also provide flood control for the upper Willamette Valley and produce hydroelectric power for the area.

Looking back on 2022, CwM is proud of the work we have done and new relationships we have built within the water resources, water rights, and water conservation fields. We would like to thank all of our amazing clients and partners for playing a pivotal role in our success and for making 2022 an excellent year. Now, we are excited to take on new challenges in 2023!

Our 2022 just would not have been complete without a site visit in the snow. Before the Holiday break, CwM staff had the opportunity to visit a beautiful vineyard property in the rolling hills of central Wasco County. The goals of the visit were to identify several irrigation wells, examine the irrigation network in place on the property, and to enhance our understanding of the geomorphology and hydrogeology of the region.

Despite the snow, CwM staff were able to identify four irrigation wells and determine their hydraulic relationship based on geologic cross-sections we had prepared earlier. We also locate the trace of an extensional fault at the surface near the property and located several artesian wells lower down in the valley. The information gained from the site visit helped CwM to prepare a more robust analysis and list of recommendations for the client regarding improvements to their irrigation system and water rights portfolio.

Members of the CwM team were fortunate to attend the 11th edition of the International Symposium on Managed Aquifer Recharge (ISMAR) this month. The event is organized by the International Association of Hydrogeologists, UNESCO, and the American Society of Civil Engineers and has previously been held in locations from Adelaide to Beijing, Madrid, and Abu Dhabi, among others. This year’s conference was held in Long Beach, California and had a heavy emphasis on water issues in the Western US and similar semi-arid regions.

ISMAR is a highly focused event intended to improve research, communication, and implementation of engineered Managed Aquifer Recharge (MAR) across the globe. This year’s event included attendants from six continents with presentations on Aquifer Storage and Recovery (ASR) case studies and technological advancements, application of surface infiltration methods, biogeochemical processes related to MAR, geophysical and remote sensing technologies, and societal and governmental frameworks for expanding MAR for various purposes. Ongoing research on and practical applications of MAR are not only for groundwater level recovery, but also for improvements of groundwater quality, preventing seawater intrusion in coastal areas, and enhancing climate resilience.

Among the highlights of ISMAR 11 was a field trip around the Orange County Water District (OCWD) to view their water source management, MAR, and water recycling systems. OCWD provides high-quality drinking water to more than 2.5 million people in the Los Angeles-Anaheim area and manages the Orange County Groundwater Basin. The largest natural source of water to the District is the Santa Ana River which flows from the San Bernardino Mountains to the northeast. In east Anaheim, OCWD has developed a system of levees and adjustable dams which divert excess flows from the river into recharge channels. These channels are maintained and managed to keep infiltration rates as high as possible. In some cases, up to 100 cfs (44,880 gpm) can be diverted and recharged through the Santa Ana River recharge channels. The diversions are placed such that the recharged water is able to flow through the Shallow Aquifer and into the deeper Principal Aquifer in the basin, which is the primary groundwater source for the area. The channels also provide wildlife habitat and opportunities for recreation.

OCWD utilizes other sources of water, including precipitation, imported water from the California Aqueduct and Colorado River, and recycled wastewater. These sources of water are used for more dispersed recharge through about a dozen infiltration basins throughout the Anaheim area. These basins range from just a few feet to over 50 ft in depth and area each operated in a manner optimized to that basin. The highest performing basin is the La Palma Basin, which can infiltrate about 10 ft of water per day. At this level of infiltration, the basin can recharge about 85 cfs (38,150 gpm) continuously. The recycled water used to fill the basin is so clean that infiltration can continue at this rate for a year before maintenance is necessary.

Much of the water used for the groundwater recharge basins comes from OCWD’s Groundwater Replenishment System (GWRS). The GWRS is the largest wastewater reuse and recycling system in the world and allows OCWD to manage the arid, highly-populated Orange County Groundwater Basin sustainably. Up to 100 million gallons per day of secondary wastewater can be delivered to GWRS each day from the sanitation district. The water passes through three main phases (microfiltration, reverse osmosis, and UV treatment) before becoming high-quality drinking water, which is then used for recharge through the infiltration basins or for the OCWD seawater barrier injection wells.

Members of the CwM team recently traveled out to east-central Oregon for field work, stopping along the way to view some of the major geologic formations of the western Blue Mountains. Their trip took them through the towns of Fossil, Spray, Kimberly, Dayville, and Mitchell. In the process, they drove across 45 million years of geologic history from the Clarno Formation to the Rattlesnake Formation.

Driving south from Fossil, the team encountered several crumbling outcrops of the Clarno Formation, which consists of pale andesite and rhyolite lava flows, ash-fall deposits, and volcanic breccias. The volcanic activity that created the Clarno Formation occurred between about 55 to 40 million years ago, which predates the activation of the Cascade volcanoes. Several debris flow deposits within the Clarno preserve the seeds and leaves of palm and avocado trees, suggesting a tropical climate during this period.

The famous Painted Hills are located near Mitchell, due south of Fossil. The hills are comprised of alternating layers of bright red, yellow, gray, and black paleosols (ancient soil) that were formed in a large floodplain between about 38 and 32 million years ago. The tropical climate represented in the late Clarno Formation continued into this period but began to shift. Wet and warm periods created bright red layers of soil, rich in iron and aluminum. Yellow soils, where metals were leached out, represent shifts to cooler and drier climate. Though not visible in the image above, both the red and yellow soil layers are often dotted with 2-4 foot-wide black patches of organic rich soil. These patched formed where dense vegetation was clustered throughout the floodplain.

On the east side of Highway 19 between Kimberley and the John Day Highway, the pinnacle of Sheep Rock can be clearly seen for several miles. The red, greenish-gray, and pink layers that form the base of Sheep Rock belong to the John Day Formation. The red claystone layer in the foreground is the Big Basin Member, the lowest unit of the John Day Formation, which was formed 40 to 32 million years ago (same time as the Painted Hills). Moving upward on Sheep Rock you next reach the greenish-gray siltstone of the Turtle Cove Member (32 to 26 million years). Cutting across the middle of Sheep Rock is the dark brown Picture Gorge Ignimbrite, which has been precisely dated to 28.8 million years old. Finally, the upper Kimberly Member of the John Day Formation appears as a pale pink claystone that was formed 26 to 24 million years ago and is capped by the Picture Gorge Basalts that hold up the pinnacle.

The Picture Gorge Basalt Flows are a member of the much larger Columbia River Basalt Group that formed about 16 to 14 million years ago. The Picture Gorge flows originated from a series of fissures that were formed due to tectonic pressures from the subducting Farallon Plate. A total of 61 separate eruptions occurred roughly every 15,000 years, eventually producing the 1,300 foot-thick Picture Gorge sequence covering about 2,500 square miles. The John Day River has cut through many of these flows in Picture Gorge along Highway 26 and Highway 19.

The Picture Gorge basalt flows were not the only volcanic activity during this time. Starting at the same time and continuing after the flood basalts ceased, nearby volcanoes erupted and deposited hundreds of feet of ash across the region. The bright white Mascall Formation, seen here in an outcrop near Dayville, was formed between 16 and 12 million years ago from andesite and rhyolite ash. Much of the ash was deposited in large, shallow lakes or was reworked by meandering streams. The resulting volcanic tuff is very light weight and has a chalky consistency. For several million years after the Mascall Formation was deposited, the region experienced uplift and significant erosion that erased about 4 million years-worth of rock. Capping the Mascall Formation across the region is a layer of mixed cobbles, gravels, and silt that belong to the Rattlesnake Formation. This conglomerate was deposited about 8 to 5 million years ago by energetic streams flowing from the recently uplifted mountains nearby.

Sources:

Bestland, E.A., Hammond, P.E., Blackwell, D.L.S, Kays, M.A., Retallack, G.J., & Stimac, J. (2002). Geologic Framework of the Clarno Unit, John Day Fossil Beds National Monument, Central Oregon. State of Oregon Department of Geology and Mineral Industries. Open-file Report O-02-03.

National Park Service. (2013). John Day Fossil Bed National Monument, Sheep Rock Geology. U.S. Department of the Interior.

Schlicker, H.G. & Brooks, H.C. (1975). Engineering Geology of the John Day Area, Grant County, Oregon. State of Oregon Department of Geology and Mineral Industries. Portland, Oregon.

Thayer, T.P. & Brown, C.E. (1966). Geologic Map of the Canyon City Quadrangle, Northeast Oregon. United States Geological Survey.

Thayer, T.P. (1972). Geologic Setting of the John Day Country, Grant County, Oregon. United States Geological Survey.

The CwM team could not resist the early summer-like weather in the Pacific Northwest and took a “Geology-Friday” field trip into the Columbia River Gorge. Their trip took them east from Portland to the Sandy River, along the Historic Columbia River Highway through Corbett, with stops at the Latourell and Bridal Veil Falls, and back west along the banks of the Columbia River. The goal was to find outcrops of the Troutdale Formation, parts of which make up an important groundwater source in the Portland metro area and part of the City of Portland’s Columbia River Wellfield.

The Troutdale Aquifer is a sequence of silts, sands, gravels, and cobbles that were deposited starting about 3-4 million years ago and overlie much of the Miocene-age Columbia River Flood Basalts in the Portland area, filling the canyons and valleys that were cut into the basalts. The sediments of the Troutdale originated from ancient channels of the Columbia River, the many streams coming off the west slopes of the ancestral Cascades, as well as significant ashfall from the High Cascade volcanic activity. Potassium-argon dating of volcanic clasts in the Upper Troutdale suggest that deposition continued until at least 1.5 million years ago.

The Troutdale is generally divided into two subunits. The Lower Troutdale was formed primarily by deposition in ancestral channels of the Columbia River and varied from well sorted sandstone to gravel and cobble conglomerates with diverse lithologies. Both materials often exhibit strong characteristics of their depositional environment, such as cross-bedding in the sandstone and imbrication of cobbles. The Upper Troutdale exhibits greater influence from concurrent volcanic activity and primarily consists of vitric sandstone and basalt conglomerate. Both units are interlayered with much finer-grained silts and clays usually assigned to the Sandy River Mudstone Formation.  

Of the eight hydrogeologic units that form the Portland Basin Aquifer System, the Troutdale Gravel Aquifer (TGA) and the Troutdale Sandstone Aquifer (TSA) are the most important for water supply. Both aquifers are common sources of water for municipal and irrigation wells in the Portland Basin. Some City supply wells in this aquifer have been tested at more than 2,500 gallons per minute. 

The CwM team found a good exposure of the Troutdale Formation along the Historical Columbia River Highway about 2.5 miles south of the Sandy River Bridge. This particular site exposes a relatively thin section of the Troutdale around the transition from Lower to Upper members. At the base of the outcrop, the upper 20 ft of grayish lithic sandstone is exposed. Cross-bedding features characteristic of river channel deposition can be seen. About 20-25 ft of coarse cobble conglomerate was visible above the sandstone. The cobbles were almost entirely of an olivine basalt composition, which is more representative of the Upper Troutdale. At the very top of the outcrop sit large boulders of the Boring Basalt, which formed in the early Pliocene.

Sources:

Evarts, Russell. (2021). Geologic Map of the Ridgefield Quadrangle, Clark and Cowlitz Counties, Washington.

Swanson, R.D., McFarland, J.B., Gonthier, J.B., & Wilkinson, J.M. (1993). A Description of Hydrogeologic Units in the Portland Basin, Oregon and Washington. USGS Water-Resources Investigations Report 90-4196.

Tolan, T.L. & Beeson, M.H. (1984). Exploring the Neogene History of the Columbia River: Discussion and Geologic Field Trip Guide to the Columbia River Gorge. DOGAMI. Oregon Geology, Vol 46 (9).

The CwM team is proud to be working with the City of Wilsonville to help them manage their water rights portfolio. The City of Wilsonville holds multiple groundwater rights and a large surface water right on the Willamette River. From the late 1980s until the early 2000s, the City depended solely on groundwater from the Columbia River Basalt Group (CRBG) aquifer for municipal supply. The growing City’s demand for groundwater resulted in accelerated groundwater level declines. In 2002, the City brought their state-of-the-art water treatment facility online and switched completely to surface water. CwM was lucky to visit this facility in November, which is now being expanded in partnership with the City of Sherwood and the Willamette Water Supply Program.

The City’s rapid transition from groundwater dependence to a surface water source affords a unique opportunity to observe groundwater recovery in the Columbia River Basalts. CwM collected data from six CRBG wells in and around Wilsonville spanning 1960 to present. From the 1960s to 1988, when Wilsonville’s current groundwater system was operational, groundwater levels declined at an average rate of 1.00 ft/year. During the period before the transition to surface water, from 1988 to 2002, the groundwater levels dropped at a jaw-dropping rate of 3.59 ft/year. Amazingly, groundwater levels rebounded rapidly once pumping to meet the growing City’s needs was halted. The recovery averaged 1.33 ft/year from 2002 to 2020. As evident in the plot below, representing data from all six study wells (Wash 3561, Clac 9074, Clac 50585, Clac 8184, Clac 8043, and Clac 278), rate of recovery has slowed as levels approach 1960’s levels. Data like these demonstrate the storage volume of the aquifer and the regional rate of groundwater recharge. With this data, a new sustainable use of the CRBG in this area is  possible and gives hope for recovery in other groundwater critical areas of the state.

In February CwM-H2O staff welcomed Portland State University student-athlete Demontre Thomas II to its office for an informational interview about water resources and management. We wish Demontre much success in his future studies and career development.

CwM-H2O staff enjoyed the sunny late winter weather while clearing trash from and planting 60 daffodil bulbs in the curb-side swale neighboring its office building on SE MLK Jr. Blvd. This 139-foot swale is enrolled as part of the City of Portland’s Green Street Stewards program. Goals of the program include maintaining urban rain gardens that collect and filter storm water, prevent pollutants from reaching local watersheds, and increasing green spaces in the city. These flowers will also brighten up a vital business district and busy traffic corridor for years to come.