Abstract. To investigate the physicochemical characteristics and sources of brown carbon (BrC) in North China, we collected fine aerosols (PM2.5) at an urban site in Tianjin over a 1-year period. We measured the ultraviolet (UV) light absorption and excitation emission matrix (EEM) fluorescence of the water-soluble BrC (WSBrC) and the water-insoluble but methanol-soluble BrC (WI-MSBrC) in the PM2.5 using a three-dimensional fluorescence spectrometer. Average light absorption efficiency of both WSBrC (Abs365, WSBrC) and WI-MSBrC (Abs365, WI-MSBrC) at 365 nm was found to be highest in winter and distinct from season to season. The biological index (BIX) and fluorescence index (FI) of WSBrC showed an opposite seasonal pattern to that of the humification index (HIX) with lower values in summer, implying that the secondary formation and further chemical processing of aerosols were intensive in summer than in other seasons. Whereas in winter, the higher HIX together with the higher BIX and FI of WI-MSBrC suggested that the BrC loading was mainly influenced by primary emissions and was relatively water-soluble. Based on EEM, the types of chromophores in BrC were divided into humic-like substances (HULIS), including low-oxygenated and high-oxygenated species, and protein like compounds (PLOM). The direct radiation absorption caused by WSBrC and WI-MSBrC combinedly in the range of 300–400 nm was accounted for about 40 % to the total radiation (range, 300–700 nm), which emphasizes that the radiation balance of the Earth's climate system is substantially affects by the BrC and should be considered in the radiative forcing models.