• The reactor was designed by Prof. William Brune's group at Penn State. 
• In addition to being used as a source of secondary organic aerosol (SOA) particles, the PAM reactor is also used to simulate atmospheric processing of soot and other model primary organic aerosols. 
• The reactor is an aluminum cylinder 46 cm L x 22 cm W, providing an internal volume of 13.3 liters. 
• UV lamps (λ = 254 nm & 185 nm) are located inside the chamber.

There are two modes of running the reactor: 

• In the OFR254 mode, only 254 nm photons are available, due to the use of doped fused quartz lamps that do not transmit 185 nm photons. O₃ needs to be introduced in order for OH to be produced, via the reaction O₃ + hv --> O₂ + O(¹D) followed by the reaction O(¹D) + H₂O --> 2OH. O₃ is generated by irradiating O₂ at λ = 185 nm with a separate lamp outside the PAM reactor.
• In the OFR185 mode, both 254 and 185 nm photons are available due to the use of clear fused quartz lamps that transmit both 185 nm and 254 nm photons. OH and HO₂ are generated directly in the reactor from H₂O photolysis, and O₃ is also produced due to O₂ photolysis. The photolysis of O₃ produces additional OH as in the OFR254 mode. In OFR185 mode there is no need to inject O₃ into the reactor.

SOA is generated via gas-phase OH oxidation of volatile organic compounds (VOCs) and intermediate volatility organic compounds (IVOCs). The PAM reactor is operated under continuous flow conditions, as opposed to environmental chambers that are typically run in batch mode.  The OH/HO₂ and OH/O₃ ratios in the PAM reactor are similar to tropospheric ratios. The amounts of OH, HO₂, and O₃ are 100 to 10,000 times larger than in the daytime troposphere. 

• Wider range of oxidant exposure time (1–30 days vs. 1 day)
• Shorter experiment duration (minutes vs. hours or days)

• High OH concentrations required to simulate atmospherical aging timescales (10⁸ - 10¹⁰ vs. 10⁶ - 10⁷ molec cm^-3)
• High (parts-per-million) levels of O₃ required for OH production
• UV emission spectrum different than troposphere (peak λ = 254 nm vs λ > 300 nm)

• Magnitude of wall effects/interactions on measurements
• Alternative UV and Vis lamps for different radical production and photolysis applications