Arsenic (As) is a metalloid element receiving major concern due to its toxicity. This element in the ocean shows nutrient-like vertical distributions, with a change of the concentrations mostly in the euphotic zone. Earlier studies had found that As(V) is the most dominant species, followed by As(III) and methylated As; the latter two are common in the surface of the P-stressed waters. However, there was no evidence of colloidal arsenic in the ocean, even though colloids are found labile to microbes and influence the partitioning of other bioactive elements in seawater. Here we used cross-flow ultrafiltration and chemical speciation methods to prove and provide the first evidence on the existence of colloidal arsenic and the molecular weight distributions of various dissolved arsenic species in the ocean. Dissolved inorganic arsenic (DIAs) showed typical nutrient-like depth profiles in the western Philippine Sea and the South China Sea. Moreover, 10–20% of the DIAs was composed of HMW-DIAs, which is discovered for the first time. Besides, nearly all the HMW-DIAs was As(V). Dissolved organic arsenic (DOAs) concentrations, in contrast, displayed decreasing trends with depth, with an average concentration of 3.2±1.1 nM in the surface. 56% of the DOAs was in colloidal phase. With molecular weight fractionation and chemical methods, dissolved arsenic species in seawater is redefined. In a short-term study in the western Philippine Sea, we found clear diel variations of the HMW-As in the upper euphotic zone, indicating a rapid turnover of arsenic in colloidal phase. Positive correlations between HMW-As and HMW-DOP in the upper euphotic zone were found in both the western Philippine Sea and the South China Sea, suggesting a close linkage with phosphorus. Overall, the results prove that colloids play a major role in biogeochemical cycle of arsenic in the ocean.