Estimate of turbulent energy dissipation rate using free-fall and CTD-attached fast-response thermistors in weak ocean turbulence

The measurement of turbulence is necessary to quantify the vertical, diapycnal transport of heat, water and substances influencing climate, nutrient supply and marine ecosystems. As specialist instrumentation and ship-time are required to conduct microstructure measurements to quantify turbulence intensity, there is a need for more inexpensive and easy measurement methods. This study demonstrated that the turbulent energy dissipation rate, epsilon, estimated from fast-response thermistors Fastip Probe model 07 (FP07) with the depth-average of a > 10 m depth interval well agreed with those from current shear probes to a range of 10(-11) W/kg (m(2)s(-3)) in the two casts of the most accurate and stable free-fall vertical microstructure profiler, VMP6000 in the Oyashio water. This range cannot be measured with velocity shear probes equipped in smaller profilers in which the lower limit of epsilon > O (10(-10)) W/kg. These results extend turbulence measurements using the FP07 to 10(-11) W/kg. They may be especially useful for turbulence observations in deep oceans where epsilon is generally weak (< 10(-10) W/kg). As FP07 are much less sensitive to instrument vibrations than current shear and may be attached to various observational platforms such as temperature-conductivity-depth (CTD) profilers and floats. The CTD-attached FP07 observations near the VMP6000 profiles demonstrated their capabilities in the epsilon range of 10(-11)-10(-8) W/kg by data screening using a W-sd > 0.1(W-0.3)criterion (1 s mean lowering rate W m/s and its standard deviation W-sd) under rough conditions where the cast-mean W-sd > 0.07 m/s and the standard deviation of W-sd in each cast sigma >0.05 m/s.

Automated summary

Measurement of turbulence is crucial for understanding the vertical and diapycnal transport of heat, water, and substances affecting climate, nutrient supply, and marine ecosystems. This study demonstrates that the use of FP07 can effectively measure turbulent energy dissipation rate, especially in deep ocean observations where turbulence is generally weak. The results extend the range of turbulence measurements using the FP07 and highlight its applicability in turbulent observations.