UCMR5 is Coming!

UCMR5 is Coming!

The United States Environmental Protection Agency (EPA) announced the reproposed Revisions to the Unregulated Contaminant Monitoring Rule (UCMR5) for Public Water Systems. This action fulfills a key commitment in EPA’s PFAS Action Plan by proposing monitoring for 29 per- and polyfluoroalkyl substances (PFAS) in drinking water. The action also proposes monitoring for lithium. The UCMR5 proposal includes monitoring for six PFAS that were part of UCMR3, now using new analytical methods that support lower reporting levels. The proposal would require pre-sampling preparations in 2022, sample collection from 2023-2025, and reporting of final results through 2026. The proposed rule reflects a significant increase in the number of participating small systems, from the typical 800 to approximately 6,000 small systems, dependent on appropriations.


EPA will host two identical virtual meetings (via webinar) on April 6 and 7, 2021, to discuss the proposed UCMR 5. The meeting scope will include proposed monitoring requirements, analyte selection, analytical methods, laboratory approval process, and ground water representative monitoring plans (GWRMPs). EPA will provide additional information once the proposal is published in the Federal Register.


BSK has notified the EPA of our intent to participate in the UCMR 5 study.

BSK Associates Laboratory

BSK Associates’ Laboratory was recently tapped by Battelle Memorial Institute (Battelle) to perform analytical testing for the Marine Corps Logistics Base in Barstow, California. Services include testing and reporting of numerous analytical constituents in drinking water and groundwater matrices to support the installation’s compliance programs. The contract is in place through October 2022. We appreciate the opportunity and look forward to working with Battelle on this project.

BSK Provides Testing Support After Fire Devastation

Metals analysis determines extent of soil contamination after fires.

Fires of recent magnitude have caused a danger to the environment that could potentially take years to clean up. Any building that has burned to a non-salvageable degree has the potential to cause toxic pollution. Immediate concerns include materials and finishes that were used in the construction of these buildings. Most paints used until 1978 contained lead, and from the 1940s to the 1970s, PCB’s were widely added as preservatives. And, until 1990, they also contained mercury. These heavy metals were used to improve flow, durability, flexibility and ironically, to increase resistance to fire damage and moisture. When plastic is burned it also releases toxic chemical fumes (like dioxins, furans and styrene gas) into the air that is harmful for humans and the environment. Many destroyed structures had roofs that may have been shingled in asbestos and filled with treated wood that can release arsenic and chromium when burned. An incinerated television can expose heavy metals such as cadmium and lead. Even seemingly innocuous items, such as collectible antique Fiesta ware crockery, may contain radioactive uranium. Mercury can leak from old thermometers and there may be radioactive isotopes from burned-up antique crock ware, cupboards of incinerated household cleaners, and asbestos from old siding.
Cleanup crews will be looking for things like burned bottles of bleach, melted cans of paint, and corroded car batteries, which will then be tagged and removed. Samples of the surrounding soil are collected for testing, and if needed, will scrape away layers to get to clean earth, free from oil and gasoline. Heavy metals, chemicals and biological contaminants left behind demand a cleanup of extraordinary scale, before any permanent return is safe. It is only after the properties have received certification that they have been remediated that residents can begin rebuilding.
BSK Analytical has vast experience testing soil samples after devastating fires. Our laboratory routinely analyzes soils for metals on a rush basis at very low detection levels. We have automated sample digestion and preparation equipment to achieve higher throughput of samples for this purpose. Our 6 automated systems can prepare over 400 samples overnight for analysis the next morning. In addition, our state-of-the-art autosampler provides for sample introduction that greatly optimizes fast analysis on the ICP/MS without sacrificing low reporting sensitivity.
BSK’s expertise includes the ability to analyze Mercury by ICP/MS rather than the more traditional Cold Vapor Atomic Absorption (CVAA) method. We have perfected ICP/MS mercury analysis allowing for only one digestion and one analysis for the CAM 17 metals, rather than having to perform them separately. ICP/MS is a preferred method for mercury when analyzing samples from a fire site because of the potential for the presence of volatile organics such as benzene generated by melted piping. Some volatile organics can cause positive interference for mercury when analyzed by CVAA.
We are deeply saddened by the devastation felt by those in the communities that fell victim to the fires, but we are excited for the opportunity to be part of the effort to help these communities recover and rebuild.
For more information on wildfires and resulting impacts on water bodies and drinking water please click here to watch this free webinar featured in the EPA ‘s September webinar series.

Baseline study for the Stockton WWTP

AECOM, one of the largest Engineering companies in the world requested a series of analytical tests which are seldom performed at a competitive price.  Additionally, they required that the samples be picked-up and analyzed in a very short time frame and TAT, during a continuous 10 calendar day period.

2016 Washington and Oregon Lead Testing

2016 Washington and Oregon Lead Testing:  Local Engineering firms, Universities, Public Schools and Water Municipalities required rush analysis of Lead on drinking water sources inside schools, offices and miscellaneous buildings.