The spatial distribution of sea surface fCO2 (fCO2w) with its controlling mechanisms and related air-sea exchange fluxes in the East China Sea (ECS) in fall 2006 was investigated. We performed the underway measurements of the air and sea surface fCO2, and hydrographic variables from November 6th to 16th 2006 during the field survey (OR1-815). The results showed that fCO2w ranged from 322.9 to 519.4μatm with an average of 359.8±20.3μatm (n=1425). The fCO2w in fall spatially exhibited a unique distribution pattern with four distinctive areas (e.g., Changjiang estuary (averaged: 422.1±39.6μatm), China coastal (367.1±9.1μatm), shelf (356.1±11.7μatm) and upwelling waters in northeastern Taiwan (376.4±11.7μatm). The highest fCO2w (>400μatm) was observed within the outer Changjiang estuary, which waters were cold and less saline with high chlorophyll-a and nutrient concentrations. Additionally, fCO2w levels apparently decreased from near-shore river mouth to offshore regions with contents which were near the whole averaged values. Based on empirical algorithms developed from SST and chlorophyll-a data in summer, the contributions of temperature, biological and vertical mixing effects on spatial fCO2 variations could be respectively estimated in four aforementioned areas of the ECS shelf. Consequently, variations on contributions of temperature and biological effects were less than 20μatm respectively among them, but that due to vertical mixing effect was greater than 100μatm. It suggests vertical mixing as the main factor controls the spatial fCO2 variation in the ECS in fall. In summer, a high CO2 uptake via biological activity takes place within the Changjiang plume in which high nutrients induce high biomass growth, and finally the CO2 was stored in subsurface and bottom layers of inner ECS shelf instead of being exported to the deep ocean. Further, the enriched-CO2 waters in subsurface layer would be brought to the surface in fall via vertical mixing. This effect would enhance the fCO2w contents in the surface, further hinder the CO2 uptake, and finally result in a net release of CO2 to the atmosphere from Changjiang plume area. However, the whole ECS shelf in fall acted as a weak sink of atmospheric CO2 with an averaged air-to-sea flux of -0.7 ± 0.9 molm-2yr-1. The results we obtained are not consistent with those reported by previous studies, which show the ECS as a CO2 source to the atmosphere in fall. It indicates small-scale spatial surveys which were previously performed in Changjiang estuary and northern ECS can’t be a representative of the whole ECS shelf.