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Summer Air Sampling
Technical Insight Β· Summer 2026

When Wildfire Season, Ozone, and Ag Drift Land at the Same Time

June 2026 Β· 12 min read Β· By Tisch Environmental
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Summer Air Sampling
3Monitoring Windows
JunePeak Overlap Month
5+EPA Methods Covered

June doesn't wait. Wildfire event response, peak ozone season, and agricultural pesticide drift monitoring frequently land in the same deployment calendar β€” and field teams that aren't prepared in advance find themselves scrambling for equipment, media, and method documentation all at once.

This bulletin is for programs that want to be ready before the season peaks. We've broken down the three primary monitoring scenarios that overlap in summer months, the specific instruments and media that fit each one, and a pre-deployment field checklist you can use before your next site visit.

Why June Is the Critical Month

Each of the three summer monitoring scenarios has its own driver β€” but they converge in a narrow seasonal window that makes preparation more important than at any other time of year.

The three overlapping monitoring demands of summer:

Wildfire Event Response +
Wildfire smoke events have expanded dramatically in geographic reach and duration over the past decade. When a major fire event occurs, air monitoring programs across downwind states may be activated simultaneously β€” requiring rapid deployment of SVOC-capable sampling equipment to characterize smoke composition and support public health response. The challenge is that these events don't follow a schedule, and equipment needs to be verified and ready before the activation call comes.
Peak Ozone Season +
Ground-level ozone formation is driven by heat, sunlight, and the presence of NOx and VOC precursors β€” which means summer afternoon conditions in most of the continental US create peak ozone formation periods. For PMβ‚‚.β‚… compliance monitoring programs, this is also the period where thermal stress on low-volume samplers is highest, making flow stability and NIST-traceable calibration verification most important.
Agricultural Pesticide Drift Monitoring +
Growing season applications of organochlorine and organophosphate pesticides create airborne drift that can affect communities adjacent to agricultural areas. Monitoring programs supporting pesticide drift investigations require high-volume samplers with PUF media capable of capturing semi-volatile OC and OP compounds per established EPA compendium methods. The seasonal window for these applications corresponds almost exactly with peak ozone season.

TE-PUF High-Volume Sampler: SVOC Recovery Under Field Conditions

TO-4A / TO-9A Compatible Β· 225 L/min Nominal Β· PUF/XAD-2 Media Configuration

Wildfire smoke is a complex mixture of particulate matter, semi-volatile organic compounds, polycyclic aromatic hydrocarbons, and dioxins/furans β€” all of which require different capture strategies. High-volume PUF sampling is the established method for SVOC characterization in smoke events, providing the filter and sorbent combination that captures both particulate-bound and vapor-phase compounds in a single 24-hour sample run.

The TE-PUF High-Volume Sampler is designed specifically for this operating environment. The PUF/XAD-2 media configuration maintains capture efficiency under the variable pressure and temperature conditions common in the field, and the system is compatible with the TO-4A and TO-9A compendium methods used for OC/OP pesticide and dioxin/furan characterization β€” making it a dual-purpose tool for programs that monitor both wildfire events and agricultural drift.

What Problem It Solves

Wildfire event response requires equipment that can be deployed quickly, run unattended for 24-hour periods, and produce samples with defensible chain-of-custody documentation. The TE-PUF HiVol handles all three β€” the integrated media housing maintains sample integrity from collection through laboratory receipt, and the flow rate stability ensures that 24-hour volume totals meet method requirements even when ambient conditions change through the sampling period.

Key Applications

Where the TE-PUF HiVol fits in summer monitoring:

Wildfire Smoke SVOC Characterization +
Smoke event response programs use PUF/XAD-2 high-volume sampling to characterize semi-volatile organic compound composition in smoke plumes. The TO-9A method covers dioxins and furans specifically, while TO-4A addresses organochlorine pesticides that may be present in smoke from agricultural or vegetation fires. A single TE-PUF HiVol deployment can generate samples for both method suites from a single 24-hour run.
Agricultural Pesticide Drift β€” OC and OP Compounds +
Organochlorine (OC) and organophosphate (OP) pesticide drift monitoring per EPA 8270D and 8141A requires a high-volume sampler with PUF media capable of capturing vapor-phase and particulate-bound pesticide compounds simultaneously. The TE-PUF HiVol with PUF/XAD-2 configuration meets this requirement and supports chain-of-custody integrity with individually wrapped, pre-cleaned media available in 30 and 60 ppi configurations.
Dioxin and Furan Monitoring +
Programs monitoring for dioxin and furan emissions from combustion sources β€” including waste incineration, industrial facilities, and large-scale fire events β€” require TO-9A and Method 23 compatible sampling systems. The TE-PUF HiVol provides the high-volume flow rate and media capacity required for the low ambient concentrations typical of dioxin/furan monitoring, where detection at part-per-quadrillion levels requires sufficient sample volume for laboratory analysis.

Key Specifications

Flow Rate225 L/min nominal
Media ConfigurationPUF/XAD-2 sorbent module
Module Dimensions8" Γ— 3" PUF cartridge
Compatible MethodsTO-4A, TO-9A, EPA 8270D, EPA 8141A, Method 23
Media Options30 ppi and 60 ppi; pre-cleaned, individually wrapped

Deployment Readiness

Wildfire event response programs that keep pre-cleaned, individually wrapped PUF media in inventory β€” rather than ordering on activation β€” can deploy within hours of an event notification rather than days. Maintaining a 30-day media inventory is the single most effective preparation step for programs in wildfire-prone regions or downwind states.

TE-Wilbur Low-Volume Sampler: Flow Stability Through Summer Thermal Cycles

40 CFR Part 58 / App A Compatible Β· 16.67 L/min Β±2% Β· PMβ‚‚.β‚… and PM₁₀

PMβ‚‚.β‚… compliance monitoring during summer months presents a specific instrumentation challenge: the extended 24-hour sampling periods required by 40 CFR Part 58 coincide with the widest daily temperature swings of the year, and flow rate stability across that full thermal range directly affects the volumetric accuracy of the sample β€” and therefore the validity of the compliance data it produces.

The TE-Wilbur Low-Volume Sampler is engineered for flow stability through extended thermal cycles. NIST-traceable volumetric accuracy at 16.67 L/min Β±2% is maintained across the full operating temperature range, ensuring that the 24-hour volume total used to calculate PMβ‚‚.β‚… concentration meets the data quality objectives required for regulatory compliance reporting.

What Problem It Solves

The most common source of invalid PMβ‚‚.β‚… compliance samples in summer months is flow rate drift β€” the sampler runs the correct volume at the start of the sampling period, but thermal effects on the flow control system cause the actual flow rate to deviate from target through the overnight and early morning hours. The TE-Wilbur's flow control architecture compensates for these thermal effects continuously, not just at the start of the sampling period.

Key Applications

Where the TE-Wilbur fits in summer monitoring:

PMβ‚‚.β‚… Regulatory Compliance Monitoring +
40 CFR Part 58 compliance monitoring for PMβ‚‚.β‚… requires a Federal Reference Method or Federal Equivalent Method sampler operating at 16.67 L/min Β±2% across the full 24-hour sampling period. Summer months are when flow stability requirements are hardest to meet due to wide diurnal temperature ranges β€” and when compliance data is most likely to be scrutinized due to elevated PMβ‚‚.β‚… concentrations from ozone-season aerosol formation and wildfire smoke intrusions.
PM₁₀ Monitoring +
PM₁₀ monitoring in areas affected by agricultural dust, construction activity, and wind-blown soil is particularly relevant in summer months when dry conditions increase fugitive dust generation. The TE-Wilbur supports PM₁₀ monitoring configurations with appropriate inlet selection, providing the same flow stability and NIST-traceable accuracy required for PMβ‚‚.β‚… compliance applications.
Smoke Event PMβ‚‚.β‚… Characterization +
When wildfire smoke intrusions elevate PMβ‚‚.β‚… concentrations above NAAQS standards, compliance monitoring data from low-volume samplers becomes the regulatory basis for air quality index reporting, health advisory issuance, and exceptional events demonstrations. The accuracy and defensibility of that data depends directly on the flow stability of the sampler used to collect it.

Key Specifications

Flow Rate16.67 L/min Β±2%
Applicable Standard40 CFR Part 58, Appendix A
ParametersPMβ‚‚.β‚… and PM₁₀
CalibrationNIST-traceable volumetric accuracy
Flow ControlContinuous β€” not start-of-run only

Polyurethane Foam Substrates: Chain-of-Custody Ready for Pesticide Drift

EPA 8270 / 8141A Compatible Β· 63.5mm Γ— 76mm Β· 30 & 60 ppi Β· Pre-Cleaned

Agricultural pesticide drift monitoring requires media that can be documented from production through laboratory analysis without chain-of-custody gaps β€” because the data collected is often used to support regulatory investigations and legal proceedings where sample integrity documentation is as important as the analytical result itself.

Tisch Environmental polyurethane foam substrates are available pre-cleaned and individually wrapped, with lot-specific cleaning documentation available upon request. The 30 ppi and 60 ppi configurations cover the full range of OC and OP pesticide drift monitoring applications under EPA 8270D and 8141A, and the standard 63.5mm Γ— 76mm dimensions are compatible with the TE-PUF HiVol media housing without modification.

What Problem It Solves

The most common source of pesticide drift sample rejection at the laboratory is contamination introduced during media handling β€” either at the field site or during transport. Pre-cleaned, individually wrapped PUF substrates eliminate the field-cleaning step entirely, reducing the risk of sample contamination and the documentation burden on field teams who are often managing multiple sampling locations simultaneously.

Key Applications

Where PUF substrates fit in summer monitoring programs:

Organochlorine Pesticide Monitoring β€” EPA 8270D +
OC pesticide drift monitoring per EPA 8270D requires PUF media capable of capturing semi-volatile compounds in both vapor phase and particulate-bound form. The 30 ppi PUF substrate is the standard configuration for OC monitoring applications, providing the surface area and void volume needed for quantitative capture of target compounds at typical ambient drift concentrations.
Organophosphate Pesticide Monitoring β€” EPA 8141A +
OP pesticide compounds are generally more polar and less persistent than OC pesticides, which affects both sampling strategy and media selection. EPA 8141A monitoring for OP pesticide drift typically uses the 60 ppi PUF configuration, which provides higher surface area for polar compound capture. Pre-cleaned media with documented extraction blank results is particularly important for OP monitoring because the lower ambient concentrations involved require lower method detection limits.
High-Capacity Configurations for Extended Deployments +
Programs monitoring adjacent to large agricultural operations during active application seasons may require extended 48 or 72-hour sampling periods to capture the full drift event. High-capacity PUF configurations β€” using tandem media sections or XAD-2 backup sorbent β€” provide the additional capacity needed for extended runs without sacrificing recovery efficiency or chain-of-custody integrity.

Key Specifications

Dimensions63.5mm Γ— 76mm (standard)
Pore Sizes30 ppi and 60 ppi
PreparationPre-cleaned, individually wrapped
Compatible MethodsEPA 8270D, EPA 8141A, TO-4A, TO-9A
DocumentationLot-specific cleaning records available on request

Method Quick Reference

A consolidated reference for the EPA methods most commonly required across the three summer monitoring scenarios covered in this bulletin.

Application Sampler Reference Method
Wildfire SVOC TE-PUF HiVol TO-4ATO-9A
PMβ‚‚.β‚… Compliance TE-Wilbur LV 40 CFR 58 App A
Pesticide Drift OC HiVol + PUF EPA 8270D
Pesticide Drift OP HiVol + PUF EPA 8141A
Dioxins / Furans TE-PUF HiVol TO-9AMethod 23

Summer Pre-Deployment

Field Checklist

Leak integrity check completed post-transit β€” verify before every deployment, not just initial setup
Filter weights stabilized β€” pre and post conditioning logged with date, time, and balance ID
Flow rate verified against NIST-traceable transfer standard β€” document actual vs. target flow
Calibrator batteries fully cycled β€” do not rely on a partial charge for a 24-hour deployment
Backup media loaded and documented β€” pre-cleaned PUF substrates with lot numbers recorded
Chain-of-custody documentation current, signed, and on-site before sample collection begins

Getting Your Program Ready Before the Season Peaks

The programs that respond most effectively to summer monitoring demands are the ones that treat preparation as a continuous process rather than a reactive one. That means keeping media inventory current, verifying equipment between seasons, and ensuring that calibration documentation is up to date before deployment β€” not during it.

If you're unsure whether your current equipment and media inventory covers the scenarios outlined in this bulletin, our engineering team can help you audit your sampling configuration and identify any gaps before the season peaks.