Radon in Eastern Washington

The Findings of the Bonneville Power Administration

The Findings of the Environmental Protection Agency

The Geography of Washington

Washington is divided into several distinctive regions: the Okanogan Highlands, the Columbia Basin, the Blue Mountains, the Cascade Mountains, the Puget Lowlands, the Coastal Mountains, the Columbia River Gorge, and the Coastal Hills. Areas east of the Cascade Mountain Range are considered part of Eastern Washington, and have higher rates of radon than the Western part of the state. The Okanogan Highlands in Northeastern Washington are dominated by the Columbia River valley and a few other north-trending river valleys. Less than %20 of the area is characterized as "gently sloping" and the local relief is 1000-3000 feet. The Columbia Basin is in the southeastern portion of the state, bounded by the Cascade Range on the west and by the Columbia and Spokane rivers to the North. There are irregular plains of low relief (100-300 feet), and open hills of moderate to high relief (300-3000 feet). The Blue Mountains lie in the Southeastern portion of the state and are characterized by open low mountains with 1000-3000 feet of relief. The Cascade Mountains divide the state in Eastern and Western half, and are high mountains where relief exceeds 3,000 feet. East of the Cascades, rainfall is typically between 9 and 15 inches per year.

The Geology of Eastern Washington

The Cascade Mountains can be divided into two geologic terrains: a northerly terrain of primarily Mesozoic metamorphic rocks intruded by Mesozoic and Tertiary granitic rocks, and a southerly terrain composed of Tertiary and Holocene volcanic rocks. These Holocene volcanic centers are responsible for thick volcanic ash deposits east of the Cascades. A layer of Miocene basaltic volcanic rocks of the Columbia Basin are underlain by an extensive glaciofluvial outwash and eolian and lacustrine deposits. The mountainous northeast and north-central portion of the state is underlain by Precambrian sedimentary rocks, Paleozoic sedimentary rocks, and Mesozoic metamorphic rocks. Each layer is intruded by Mesozoic and Tertiary granites in these these regions. As ice from the glaciation of the late Pleistocene receded from Northeastern Washington, large lakes formed behind ice dams along the ancestoral Columbia River valley. Massive floods periodically carried large quantities of alluvium along the entire river drainages, and in some regions valleys were eroded all the way down to the underlying basalt bedrock. Aerial radiometric data shows that in the westernmost portions of the Okanogan Highlands, Mesozoic and Tertiary granites have low equivalent Uranium (eU) signatures, while the eastern portions have granites and some metamorphic rocks with eU signatures approaching 5 ppm eU. Although much of the Columbia basin is underlain by basaltic rocks low in uranium, most of this area showed eU signatures between 2 and 3 ppm because of the extensive superficial cover of the Quaternary and Holocene glaciofluvial, lacustrin, and eolian deposits, derived from rocks in Northeast Washington and Northern Idaho with higher uranium content. The east flank of the Southern Cascades and the Blue Mountains lack this superficial cover, and show eU readings between 0.5 ppm and 1.5 ppm. Uranium occurences and deposits in Washington are largely associated with granitic and metamorphic rocks in the Okanogan Highland region north of Spokane and with Tertiary sedimentary rocks. Alluvium along stream valleys of the granitic terrains of the Okanogan Highlands are sites of potential superficial uranium deposits.¹⁴ Because of their relative youth, these Holocene uranium deposits are low in radioactivity, and moreover, they are found in the floodplains of streams or in wetlands, where construction is unlikely.

Bonneville Power Administration

In 1987, the Bonneville Power Administration's Residential Standards Demonstration Program (RSDP) completed three and twelve-month studies of radon concentrations of indoor air for homes in the Pacific Northwest. With the help of researchers from Lawrence Berkeley Laboratories (LBL), homes constructed under Model Conservation Standards (MCS) were tested as well as control dwellings that met construction codes and were recently built. These homes were both single and multifamily site-built dwellings. Of the 331 three month test sites, 155 were MCS and 176 were control. Of the 343 sites in the twelve month group, 161 were MCS and 182 were controls. Measurements were made with passive samplers (Track-Etch detectors) manufactured by the Terradex Corporation, Walnut Creek, CA. The experiment was conducted during the winter in order to minimize ventilation. The RSDP study showed that there was no significant difference in radon levels between homes built to MCS standards and other homes. The Residential Weatherization Program of 1988 conducted a similar experiment in homes in Washington, Oregon, Idaho, and Montana. Because the number of homes tested was weighted in favor of Washington, these results must not be interpreted on a region-wide basis; this data has been provided for a general assay of radon in these states.

Table of Results of the RSDP Experiment of 1987
Table of Results of the Residential Weatherization Program of 1988

The Findings of the EPA¹⁵

By Sections 307 and 309 of the Indoor Radon Abatement Act (1988), the EPA was directed to identify areas of the United States with high radon potential. With the USGS, and the Association of American State Geologists, the EPA has produced a series of documents and maps on the subject. The documents are based on both geological data and measured radon levels in homes. The largest source of data is from the State/EPA Residential Radon Survey (Ronca-Battista, et al, 1988; Dziuban, et al, 1990). The surveys collected 2-7 day indoor radon measurements using charcoal canister radon detectors. Nationwide, nearly 60,000 homes were tested in the survey. The second source of indoor data comes from residential surveys conducted on a regional basis, such as the RSDP program of the Bonneville Power Administration. The radon levels measured by the EPA and the State of Washington in the winter of 1990-91 was based on population, because homes tested were randomly selected from existing housing stock. For this reason, interpretations of the data for a whole county's surface area may not be absolutely accurate. The highest readings for radon occurred in the Okanogan Highlands, with three counties that averaged levels above 4 pCi/L. Most of the north-central and eastern parts of the state were measured to have levels between 2 and 4 pCi/L. All counties west of the Cascades were below 1 pCi/L.

Table: Radon Levels by County in Eastern Washington