TY - JOUR
T1 - Moored observations of turbulent mixing events in deep lake garda, Italy
AU - van Haren, Hans
AU - Piccolroaz, Sebastiano
AU - Amadori, Marina
AU - Toffolon, Marco
AU - Dijkstra, Henk A.
N1 - Funding Information:
Lanzillo(IMAU)lasting temperature onlyfor assisting on the preparationof thesensor efforts, and F. Cassano and F. temperature string. This project was funded by the Faculty of Science of Utrecht University through a grant to HD
Funding Information:
and wuse as supported by the National Marine Facilities (NIOZ) and the DICAM (University of Trento). The authors declare no conflict of interest.
Publisher Copyright:
© the Author(s), 2020.
PY - 2021/2/19
Y1 - 2021/2/19
N2 - Deep water circulation and mixing processes are responsible for the transport of matter, nutrients and pollutants in deep lakes. Nevertheless, detailed continuous observations are rarely available. To overcome some of these deficiencies and with the aim of improving our understanding of deep mixing processes, a dedicated yearlong mooring comprising 100 high-resolution temperature sensors and a single current meter were located in the deeper half of the 344 m deepest point of the subalpine Lake Garda, Italy. The observations show peaks and calms of turbulent exchange, besides ubiquitous internal wave activity. In late winter, northerly winds activate episodic deep convective overturning, the dense water being subsequently advected along the lake-floor. Besides deep convection, such winds also set-up seiches and inertial waves that are associated with about 100 times larger turbulence dissipation rates than that by semidiurnal internal wave breaking observed in summer. In the lower 60 m above the lake-floor, however, the average turbulence dissipation rate is approximately constant in value year-around, being about 10 times larger than open-ocean values, except during deep convection episodes.
AB - Deep water circulation and mixing processes are responsible for the transport of matter, nutrients and pollutants in deep lakes. Nevertheless, detailed continuous observations are rarely available. To overcome some of these deficiencies and with the aim of improving our understanding of deep mixing processes, a dedicated yearlong mooring comprising 100 high-resolution temperature sensors and a single current meter were located in the deeper half of the 344 m deepest point of the subalpine Lake Garda, Italy. The observations show peaks and calms of turbulent exchange, besides ubiquitous internal wave activity. In late winter, northerly winds activate episodic deep convective overturning, the dense water being subsequently advected along the lake-floor. Besides deep convection, such winds also set-up seiches and inertial waves that are associated with about 100 times larger turbulence dissipation rates than that by semidiurnal internal wave breaking observed in summer. In the lower 60 m above the lake-floor, however, the average turbulence dissipation rate is approximately constant in value year-around, being about 10 times larger than open-ocean values, except during deep convection episodes.
KW - Convective cooling
KW - Deep Lake Garda
KW - Internal waves
KW - Turbulent overturning
KW - Yearlong high-resolution moored temperature observations
U2 - 10.4081/jlimnol.2020.1983
DO - 10.4081/jlimnol.2020.1983
M3 - Article
AN - SCOPUS:85102891369
SN - 1129-5767
VL - 80
SP - 1
EP - 18
JO - Journal of Limnology
JF - Journal of Limnology
IS - 1
M1 - 1983
ER -