Maximum Likelihood Spectral Fitting: The Batchelor Spectrum

Ruddick, Barry; Anis, Ayal; Thompson, Keith R.

doi:10.1175/1520-0426(2000)017<1541:mlsftb>2.0.co;2

Cited by 158 publications

(215 citation statements)

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“…Rate of dissipation and vertical diffusivity: The rate of dissipation of turbulent kinetic energy e was computed from the SCAMP data by fitting the measured temperature gradient spectra to the theoretical Batchelor spectrum using 25-cm segments and the maximum-likelihood spectralfitting method developed by Ruddick et al (2000; and recently improved by Steinbuck et al [2009]). These methods provide a good fit to the theoretical Batchelor spectrum and give reliable criteria to reject bad segments.…”

Section: Methodsmentioning

confidence: 99%

Poincaré wave–induced mixing in a large lake

Bouffard¹,

Boegman²,

Rao

2012

Limnology & Oceanography

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A 10,000-km 2 hypoxic 'dead zone' forms, during most years, in the central basin of Lake Erie. To investigate the processes driving the hypoxia, we conducted a 2-yr field campaign where the mixing in the lake interior during the stratification period was examined using current meters and temperature-loggers data, as well as . 600 temperature microstructure profiles, from which turbulent mixing was computed. Near-inertial Poincaré waves drive shear instability, generating , 1-m amplitude and 10-m wavelength high-frequency internal waves with , 1-m density overturns that lead to an increase in turbulent dissipation by one order of magnitude. The instabilities are associated with enhanced vertical shear at the crests and troughs of the Poincaré waves and may be correlated with the local gradient Richardson number. Poincaré wave-induced mixing should be an important factor when the Burger number , 0.25. The strong diapycnal mixing induced by the Poincaré wave activity will also significantly modify the energy-flux paths. For example, we estimate that, in Lake Erie, 0.85% of the wind energy is transferred to the lake interior (below the surface layer); of this, 40% is dissipated in the interior metalimnion and 60% is dissipated at the bottom boundary. In smaller lakes, 0.42% of wind energy is transferred to the deeper water, with 90% dissipated in the boundary and 10% in the interior metalimnion.

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Section: Methodsmentioning

confidence: 99%

Poincaré wave–induced mixing in a large lake

Bouffard¹,

Boegman²,

Rao

2012

Limnology & Oceanography

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“…SCAMP is a loose-tether instrument that free falls at 10 cm s 21 recording temperature, conductivity, temperature gradient, and fluorescence at 100 Hz (Ruddick et al 2000). The workboat operated within 1 km of the R/V Tangaroa and profiles were typically located between the vessel and the buoyed DVA.…”

Section: Methodsmentioning

confidence: 99%

“…The temperature microstructure were divided into 4-m sections, each containing around 4000 data points, which, in turn, were divided into 64-point segments for the spectral fitting. The goodness-of-fit criterion based on a comparison of the observed to theoretical temperature gradient spectrum (Ruddick et al 2000) and a noise threshold were used, so that 45% of e samples were rejected.…”

Section: Methodsmentioning

confidence: 99%

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Internal waves downstream of Norfolk Ridge, western Pacific, and their biophysical implications

Stevens

Sutton

Law

2012

Limnology & Oceanography

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An 11-d quasi-Lagrangian surface layer experiment to the east of Norfolk Island tracked a 140-m-deep drifting vertical array (DVA) of instruments, including conductivity sensors, thermistors, and current meters. These are the first in situ data from the area to measure large-amplitude internal waves. The observations show isotherm peak-to-peak excursions reaching 50 m and were dominated by the semidiurnal forcing frequency. The DVA exhibited horizontal loops at the semidiurnal tidal frequency as it tracked water at depths of 80-140 m to within 10% of total horizontal displacement. The large vertical isotherm excursions generated substantial vertical shear. Temperature microstructure estimates of the vertical diffusivity of scalar properties at 70-m depth, around the center of the thermocline, were on the order of 10 24 m 2 s 21 and around an order of magnitude larger at shallower depths. When combined with nitrate data, this implies vertical fluxes of nitrate in the pycnocline of , 1 mmol m 22 d 21 . The internal waves also potentially cause an interaction between the variability in tidal forcing and the diurnal radiation cycle that influences chlorophyll in the deep chlorophyll maximum. The average effect of the internal wave was to increase the light level for a particular isotherm over the static case. The internal waveinduced velocities were strong enough to dominate phytoplankton rise speeds and so potentially played a role in the formation and persistence of an observed Trichodesmium bloom.

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“…To avoid these issues, we chose the maximum likelihood estimator (MLE) technique for spectral fitting (Priestley 1981;Bendat and Piersol 2000). Ruddick et al (2000) successfully applied the MLE technique to Batchelor fitting of temperature gradient spectra. The MLE for n samples is: (12) where f(a i ) is the probability density function of the i th observation of variable a, which for our application is the estimated velocity spectra .…”

Section: Data Processingmentioning

confidence: 99%

Estimating turbulent kinetic energy dissipation using the inertial subrange method in environmental flows

Bluteau

Jones

Ivey

2011

Limnology & Ocean Methods

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The inertial subrange dissipation method, where spectral fitting is performed on the velocity spectra inertial subrange, is commonly used to estimate the dissipation of turbulent kinetic energy e in environmental flows. Anisotropy induced from mean shear or stratification can inhibit the use of certain velocity components or even make the inertial subrange unusable for estimating e but often this issue is ignored, potentially leading to large errors in estimated e. We developed and tested a methodology to determine reliably e with the inertial subrange, taking into consideration the sampling program, the instrument, and the flow characteristics. We evaluated various misfit criteria for identifying the inertial subrange and described the statistical methods appropriate for spectral fitting. For shear flows, we defined a parameter B = L s /h, where L s is the shear length scale and h is the Kolmogorov length scale that describes the extent of anisotropy in the inertial subrange; this ratio of length scales is analogous to the ratio for stratified flows I = L o /h, where L o is the Ozmidov length scale. We assessed our methodology by applying it to two data sets with very different shear and stratification. When B was low, the high shear led to anisotropy and precluded the estimation of e. To enable successful application of the inertial subrange dissipation method, we recommend measuring the mean stratification and the mean velocity profile to estimate shear. The Richardson number relates the two length scales Ri = (L s /L o ) 4/3 and shear dominates the largest turbulent length scales as Ri decreases, i.e., L s < L o .

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Maximum Likelihood Spectral Fitting: The Batchelor Spectrum

Cited by 158 publications

References 14 publications

Poincaré wave–induced mixing in a large lake

Poincaré wave–induced mixing in a large lake

Internal waves downstream of Norfolk Ridge, western Pacific, and their biophysical implications

Estimating turbulent kinetic energy dissipation using the inertial subrange method in environmental flows

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