Biological production in the NE Pacific and its influence on air‐sea CO 2 flux: Evidence from dissolved oxygen isotopes and O 2 /Ar

We determine rates of gross photosynthetic O 2 production ( GOP ) and net community O 2 production ( NCP ) using the triple oxygen isotope and O 2 /Ar approach on two spring and two late summer meridional transects of the NE Pacific. Observed GOP and NCP in the subtropical (89 ± 9 and 8.3 ± 1.3 mmol O 2 m −2 d −1 , respectively) and subarctic (193 ± 16 and 16.3 ± 3.8 mmol O 2 m −2 d −1 ) were in agreement with rates previously determined at time series stations in each region, validating the regional representativeness of these sites. At the transition zone chlorophyll front (TZCF), which migrates seasonally from 32°N in spring to 40°N in summer, GOP and NCP were elevated by 2–4× compared to adjacent areas. Coincident with the TZCF, increases in surface nitrate concentration and extensive changes in phytoplankton community composition were observed. HPLC pigment data indicated substantial increases in a prymnesiophyte (e.g., coccolithophore) biomarker at the TZCF on a spring and summer cruise, and a diatom biomarker on the spring cruise. Increases in remotely sensed surface particulate inorganic carbon concentration were also observed at the TZCF on all four cruises, indicating that coccolithophore production may contribute to increased productivity at the TZCF. Meridional trends in observed air‐sea CO 2 flux on each cruise resembled those of the biologically induced CO 2 flux ( NCP ), but with an overprinting of the response of air‐sea CO 2 exchange to summer warming. A simple carbon budget based on regional CO 2 flux climatology demonstrates the importance of NCP for net annual air‐sea CO 2 uptake, although slow air‐sea equilibration and seasonal solubility effects obscure this term.