The influence of water and radicals on SOAs produced by beta-pinene ozonolysis was investigated at 298 and 288 K using a laminar flow reactor. A volatility tandem differential mobility analyzer (VTDMA) was used to measure the evaporation of the SOA, enabling the parametrization of its volatility properties. The parameters extracted included the temperature at which 50% of the aerosol had evaporated (T-VFR0.5) and the slope factor (S-VFR). An increase in S-VFR indicates a broader distribution of vapor pressures for the aerosol constituents. Reducing the reaction temperature increased S-VFR and decreased T-VFR0.5 under humid conditions but had less effect on T-VFR0.5 under dry conditions. In general, higher water concentrations gave lower T-VFR0.5 values, more negative S-VFR values, and a reduction in total SOA production. The radical conditions were changed by introducing OH scavengers to generate systems with and without OH radicals and with different [HO2]/[RO2] ratios. The presence of a scavenger and lower [HO2]/[RO2] ratio reduced SOA production. Observed changes in S-VFR values could be linked to the more complex chemistry that occurs in the absence of a scavenger and indicated that additional HO2 chemistry gives products with a wider range of vapor pressures. Updates to existing ozonolysis mechanisms with routes that describe the observed responses to water and radical conditions for monoterpenes with endocyclic and exocyclic double bonds are discussed.