The annual cycle of energy input, modal excitation and physical plus biogenic turbulent dissipation in a temperate lake

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

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The annual cycle of energy input, modal excitation and physical plus biogenic turbulent dissipation in a temperate lake. / Simpson, John; Woolway, Iestyn; Scannell, Brian et al.
Yn: Water Resources Research, Cyfrol 57, Rhif 6, 2020WR029441, 06.2021.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

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Simpson J, Woolway I, Scannell B, Austin M, Powell B, Maberly SC. The annual cycle of energy input, modal excitation and physical plus biogenic turbulent dissipation in a temperate lake. Water Resources Research. 2021 Meh;57(6):2020WR029441. Epub 2021 Mai 20. doi: 10.1029/2020WR029441

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TY - JOUR

T1 - The annual cycle of energy input, modal excitation and physical plus biogenic turbulent dissipation in a temperate lake

AU - Simpson, John

AU - Woolway, Iestyn

AU - Scannell, Brian

AU - Austin, Martin

AU - Powell, Ben

AU - Maberly, Stephen C.

PY - 2021/6

Y1 - 2021/6

N2 - A year of measurements by Doppler Current Profilers, a chain of temperature sensors and a suite of meteorological instruments has been analysed to elucidate the seasonal cycle of the dynamical response of a temperate lake (Windermere) to surface forcing. The efficiency of energy input to the lake (Eff) was determined by comparing the rate of working by the surface wind-stress RWy with the downward flux of momentum in the atmosphere. Eff was found to increase from values of ∼0.3% in winter mixed conditions, up to ∼1.2% during summer stratification, when internal seiches were present. Water column kinetic energy was similarly enhanced during stratification. Spectral analysis of the axial velocity showed that the first vertical mode was dominant during most of the stratified period with a less prominent second mode appearing in the early part of the summer. The observed periods and vertical structure of these modes generally accorded with estimates from internal wave theory based on density profiles. During stratification, pycnocline dissipation exhibited high variability linked to the surface forcing with an average, depth-integrated, pycnocline dissipation rate of 2.5x10-5 W m-2 corresponding to ∼3-4% of RWy. Over the same period, the dissipation rate in the bottom boundary layer (BBL) exhibited a marked diurnal variation unrelated to physical forcing. Acoustic backscatter indicated the presence of vertically migrating organisms with peak aggregation in the BBL around midday coinciding with maximum dissipation. During stratification, biogenic dissipation contributed an average of ∼36% of the total BBL dissipation rate of ∼5.7x10-5 W m-2.

AB - A year of measurements by Doppler Current Profilers, a chain of temperature sensors and a suite of meteorological instruments has been analysed to elucidate the seasonal cycle of the dynamical response of a temperate lake (Windermere) to surface forcing. The efficiency of energy input to the lake (Eff) was determined by comparing the rate of working by the surface wind-stress RWy with the downward flux of momentum in the atmosphere. Eff was found to increase from values of ∼0.3% in winter mixed conditions, up to ∼1.2% during summer stratification, when internal seiches were present. Water column kinetic energy was similarly enhanced during stratification. Spectral analysis of the axial velocity showed that the first vertical mode was dominant during most of the stratified period with a less prominent second mode appearing in the early part of the summer. The observed periods and vertical structure of these modes generally accorded with estimates from internal wave theory based on density profiles. During stratification, pycnocline dissipation exhibited high variability linked to the surface forcing with an average, depth-integrated, pycnocline dissipation rate of 2.5x10-5 W m-2 corresponding to ∼3-4% of RWy. Over the same period, the dissipation rate in the bottom boundary layer (BBL) exhibited a marked diurnal variation unrelated to physical forcing. Acoustic backscatter indicated the presence of vertically migrating organisms with peak aggregation in the BBL around midday coinciding with maximum dissipation. During stratification, biogenic dissipation contributed an average of ∼36% of the total BBL dissipation rate of ∼5.7x10-5 W m-2.

KW - biomixing

KW - diel vertical migration

KW - limnology

KW - seiching

KW - stratification

KW - turbulence

U2 - 10.1029/2020WR029441

DO - 10.1029/2020WR029441

M3 - Article

VL - 57

JO - Water Resources Research

JF - Water Resources Research

SN - 0043-1397

IS - 6

M1 - 2020WR029441

ER -