In this study, a MOUDI (Micro-Orifice Uniform Deposit Impactors, Model 110, MSP Corp., MN, USA), a Dichotomous (Model SA-241, Andersen Inc., Georgia, USA), and a Scanning Mobility Particle Sizer (Model 3936, TSI Incorporated, St. Paul, MN, USA, SMPS) were deployed in Jongshan, Sinjhuang, and Jhudong site to measure atmospheric aerosol mass and number concentrations. The effective density (ρeff) and dynamic shape factor (χ) calculated based on the measured number and mass concentrations were used to convert mass concentrations into number concentrations to investigate the effect of ultrafine particles (UPs) on environment. The results of back trajectory analysis showed that the atmospheric aerosols in northern Taiwan in summer came from South China Sea, Philippine Sea, and western Pacific Ocean. In the other seasons, the atmospheric aerosols mainly came from China, Russia, and Inner Mongolia autonomous region. PM2.5 concentrations in Autumn, Winter, and Spring were higher than those in summer because of the influence of dust from mainland China transported by prevailing north-eastern monsoon. The highest PM0.1 number concentration was observed in Jongshan site due to the traffic emissions from Xinsheng highway (Betha et al., 2014). The particle water soluble ions contributed higher fractions to PM2.5 than to PM0.1 because PM2.5 are aged aerosols in which large fraction of condensed water on the surface of particles may absorb inorganic salts. PM2.5 are also secondary aged particles generated by gas-to-particle partitioning or photochemical reaction (Cao et al., 2013). Mass concentration distributions in Jongshan, Sinjhuang, and Jhudong site shows bimodal distribution, in which the aerodynamic mean diameter was in the range of 4-8.5 μm, the accumulation mode was in the range of 200-800 nm. When the dust or typhoon event occurred, the bimodal distribution was changed to single modal distribution and the aerodynamic mean diameter in the range of 0.84-3.26 μm. The ρeff and χ were calculated based on the number and mass concentration measured by SMPS and MOUDI, respectively, in Jongshan and Shalu site. The bulk density obtained by Hu et al. (2012) was applied to calculate dynamic shape factor. The average ρeff of PM0.1 and PM0.1-0.18 were 0.68±0.16 and 1.06±0.32 g/cm3, respectively, the average χ were 2.06±0.19及1.45±0.16, respectively, in Jongshan site. The average ρeff of PM0.1 and PM0.1-0.18 were 0.62±0.07 and 0.93±0.16 g/cm3, respectively, the average χ were 2.30±0.21 and 1.45±0.11, respectively, in Shalu site. Based on the number and mass concentration measured in the sampling as the aforementioned, the effective density was calculated to convert the mass concentration measured by MOUDI into number concentration and surface concentration. The results showed that although the mass ratio of PM0.1/PM2.5 of 7.9±4.4 % was low, the number concentration ratio of PM0.1/PM2.5 was 89.0±5.5 %, and the surface concentration ratio was 42.1±12.8 %. Therefore, we should pay attention to the adverse effect of PM0.1 on human health.