Vertical mixing alleviates autumnal oxygen deficiency in the central North Sea.

There is an immediate need to better understand and monitor shelf sea dissolved oxygen (O 2) concentrations. Here we use high-resolution glider observations of turbulence and O 2 concentrations to directly estimate the vertical O 2 flux into the bottom mixed layer (BML) immediately before the autumn breakdown of stratification in a seasonally stratified shelf sea. We present a novel method to resolve the oxycline across sharp gradients due to slow optode response time and optode positioning in a flow "shadow zone" on Slocum gliders. The vertical O 2 flux to the low-O 2 BML was found to be between 2.5 to 6.4 mmol m -2 d -1. Episodic intense mixing events were responsible for the majority (up to 90 %) of this oxygen supply despite making up 40 % of the observations. Without these intense mixing events, BML O 2 concentrations would approach ecologically concerning levels by the end of the stratified period. Understanding the driving forces behind episodic mixing and how these may change under future climate scenarios and renewable energy infrastructure is key for monitoring shelf sea health. [ABSTRACT FROM AUTHOR]