Statistics of Internal Tide Bores and Internal Solitary Waves Observed ...

Statistics of Internal Tide Bores and Internal Solitary Waves Observed on the Inner Continental Shelf off Point Sal CA J OHN A. C OLOSI1 , N IRNIMESH K UMAR2 , S UTARA H. S UANDA3 , T UCKER M. F REISMUTH1 , AND JAMIE H. M AC M AHAN1 1 Department 2 Department 3 Integrative

of Oceanography, Naval Postgraduate School, Monterey Bay, CA

of Civil & Environmental Engineering, University of Washington, Seattle WA Oceanography Division, Scripps Institution of Oceanography, La Jolla, CA

Revised to Journal of Physical Oceanography,

August 22, 2017

Corresponding author address: J. Colosi, Department of Oceanography, Naval Postgraduate School, Monterey CA 93943

1

ABSTRACT Moored observations of temperature and current were collected on the inner continental shelf off Point Sal, California between 9 June and 8 August 2015. The measurements consist of 10 moorings in total, 4 moorings each on the 50 and 30 meter isobaths covering a 10-km along shelf distance and an across shelf section of moorings on the 50, 40, 30, and 20 m isobaths covering a 5-km distance. Energetic, highly variable, and strongly dissipating transient wave events termed internal tide bores and internal solitary waves (ISW’s) dominate the records. Simple models of the bore and ISW space/time behavior are implemented as a temperature match filter to detect events and estimate wave-packet parameters as a function of time and mooring position. Wave derived quantities include 1) group speed and direction, 2) time of arrival, time duration, vertical displacement amplitude, and waves per day, and 3) energy density, energy flux and propagation loss. In total over 1000 bore events and over 9,000 ISW events were detected providing well-sampled statistical distributions. Statistics of the waves are rather insensitive to position along-shelf but change markedly in the across-shelf direction. Two compelling results are: 1) that the probability density functions for bore and ISW energy flux are nearly exponential suggesting the importance of interference and 2) that wave propagation loss is proportional to energy flux thus giving an exponential decay of energy flux towards shore with an e-folding scale of 2-2.4 km and average dissipation rates for bores and ISWs of 144 W/m and 1.5 W/m respectively.

2

1. Introduction

1

Nonlinear internal wave generation, propagation and dissipation on the continental slope and

2

shelf is a lively topic which has garnered significant attention over the last few decades (Duda

3

and Farmer 1999; Helfrich and Melville 2006; Apel et al. 2007; Nash et al. 2012; Lamb 2014).

4

From the very first observations the inherent variability of the waves has been clear (Lee and

5

Beardsley 1974; Liu 1988; Nash et al. 2012), leading to efforts to better understand the wave

6

propagation physics. Internal wave variability can be driven by several factors including variability

7

in background stratification and currents (Lee and Beardsley 1974; Grimshaw et al. 2004), wave

8

interference (Badiey et al. 2013, 2016), turbulent dissipation (MacKinnon and Gregg 2003; Moum

9

et al. 2003, 2007b), shoaling and boundary processes (Brink 1988; Lentz and Fewings 2012),

10

horizontal plane propagation effects (Zhang et al. 2014; Duda et al. 2014), and some degree of

11

variability in the generation and propagation processes on the slope and outershelf (Colosi et al.

12

2001a; Shroyer et al. 2010).

13

While variability has been a hallmark of the observations there are in fact limited studies

14

that have quantified the statistical distributions of nonlinear internal wave characteristics (A few

15

exceptions with small ensembles are Shroyer et al. 2010, 2011; Richards et al. 2013; Zhang et al.

16

2015; Badiey et al. 2016). The work that has been done is primarily associated with the outer

17

and mid-shelf. This observational study takes on the topic of internal wave variability in the

18

inner continental shelf region using measurements obtained off Point Sal CA which is north of

19

Point Conception (Fig. 1). Here the inner shelf is generically defined as the region between the

20

50-m isobath and the outer surf zone, and the waves are expected to be influenced by complex

21

propagation and dissipation processes. Related work for Massachussets Bay has been described 3

22

by Scotti et al. (2006) and Monterey Bay inner shelf wave variability and its association with

23

up/downwelling was analyzed by Walter et al. (2014). The approach here is to break the waves

24

up into two categories, bores and internal solitary waves (ISWs), and to examine their variability

25

separately. It is, of course apparent that the ISWs are generated by the bores so there is a clear

26

dynamical connection. Because the observations come from a relatively sparse array of moorings

27

(Fig. 1) with no measurements of turbulence, the objective is not so much to pin point physical

28

processes but to assemble a large ensemble of nonlinear wave events so that statistical distributions

29

are well characterized. The statistical distributions imply certain physical processes, for example

30

the Rayleigh distribution represents randomly interfering waves. Further, by examining the large

31

scale fields of stratification and current in which the nonlinear waves are propagating and comparing

32

these conditions to the observed variability implicates certain modulating dynamical processes, such

33

as upwelling (Walter et al. 2014). Observables of interest here include (1) wave speed and direction,

34

(2) vertical displacement amplitude, time of arrival, time duration, and number of waves per day,

35

and (3) wave vertically integrated energy density, energy flux, and propagation loss. Our ensembles

F IG. 1 36 are large with over 1000 bore events and over 9000 ISW events. 37

The analysis reveals several interesting aspects of the energetic, variable, and dissipating bores

38

and ISWs some of which are summarized here. Perhaps the most compelling statistical result is

39

that the bore and ISW Probability Density Functions (PDFs) for energy observables such as flux

40

resemble those of twinkling stars (Wheelon 2003) and scintillating ocean acoustic signals (Colosi

41

2016). These PDFs are associated with wave systems in which interference effects have an impact

42

on the fluctuations. This result might help explain the observations that wave energy densities on the

43

New Jersey Continental shelf “spanned three decades” (Shroyer et al. 2010). In fact observations of

44

crossing waves and complex interference patterns in Synthetic Aperture Radar (SAR) images are 4

45

all too common (Apel et al. 1997; Ramp et al. 2004; Zhang et al. 2014) and in the present context

46

it is likely that significant internal tide interference is occurring due to remote and local internal

47

tide generation (Nash et al. 2012) as well as horizontal propagation effects. The observation of

48

interfering ISWs has also been reported on the New Jersey continental shelf and mapping techniques

49

have been developed to better visualize the wave fields (Badiey et al. 2013, 2016).

50

Dynamical modulating processes are also of keen interest. The observed wave fluctuations

51

show many timescales but if the focus is on low frequency modulation on the order of days to

52

weeks several interesting correlations emerge in the energy observables. Namely bore energy flux

53

is modulated by deep stratification variations while ISW energy flux is modulated by changes in

54

shallow main thermocline stratification. In both these cases there is no apparent modulation either

55

by the spring/neap cycle, daily inequality, or by background currents. The connection of bore flux

56

to deep stratification is due to the fact that the Point Sal shelf is fairly subcritical but close to critical

57

for semi-diurnal internal tides and so a rise/fall in deep N causes a rise/fall in flux due to changes

58

in bottom bounce amplification (Wunsch and Hendry 1972; Eriksen 1998). Similarly ISWs are

59

sensitive to upper ocean stratification as they are riding on the shallow thermocline, and the rate of

60

ISW generation from the bore is proportional to N , the density stratification(Apel 2003).

61

There is also the important issue of wave dissipation in this shallow inner shelf region. Because

62

of the large number of observed waves a detailed statistical picture emerges. In particular the

63

dependence of propagation loss on wave energy flux is close to linear: high energy waves dissipate

64

more than low energy waves as might be expected from stability analysis. This relationship means

65

that energy flux will on average decay exponentially toward shore and the observed decay scales for

66

bores and ISWs are 2.0±0.1 and 2.4±0.1 km respectively. This leads to average dissipation rates of

67

144 and 1.5 W/m for bores and ISWs, which are comparable to those of other studies (Moum et al. 5

68

2007a; Shroyer et al. 2010). The processes leading to this dissipation are unknown as the field work

69

did not include observations of mixing or turbulence.

70

Lastly an important concept must be stressed, and that is the notion that the space/time behavior

71

of these waves is strongly stochastic. There is no such thing as a typical wave and thus the PDFs

72

of the waves and the dynamical processes that shape the PDFs are the fundamental quantities to

73

be considered. To the extent that this situation is universal to inner shelf nonlinear internal waves

74

will need to be demonstrated by further observations, though many investigators have come to this

75

conclusion with regards to outer and mid shelf waves (Nash et al. 2012).

76

The organization of this paper is as follows. Section 2 describes the experimental arrangement

77

and physical setting of the Point Sal region. Section 3 explains the bore and ISW models used for

78

the interpretation of the data as well as important wave detection and signal processing techniques.

79

Sections 4 and 5 present the statistical results for bores and ISWs respectively, and section 6 has a

80

brief summary and conclusions.

2. Experimental Description and Setting

81

The observations and analysis presented in this manuscript were part of a larger Office of Naval

82

Research (ONR) effort called the Inner Shelf Department Research Initiative or Inner shelf DRI.

83

The goals of the DRI are to 1) Quantify the interactions between, and relative importance of wind,

84

eddies, surface waves, internal waves, mixing processes, and surf zone processes in driving the

85

three-dimensional circulation and stratification variability of the inner continental shelf, 2) Quantify

86

the space and time scales of transport phenomena across the inner shelf and the processes that

87

drive it, 3) Determine the impact of coastline geometry and topographic effects on the dynamical 6

88

processes in (1), and the transport phenomena in (2), and 4) Evaluate the ability of rapidly evolving,

89

state-of-the-art hydrostatic and non-hydrostatic circulation and wave models to simulate the key

90

processes driving circulation, stratification and transport variability on the inner shelf. The Point

91

Sal region located North of Point Conception CA was chosen as a field testing site for the activities

92

of the DRI because of its strong wind driven circulation, eddy field, surface waves, and internal

93

waves, and its diverse coastline and inner shelf topography (Fig. 1 and also See (Suanda et al.

94

2016)). Regional oceanographic background information can be found in studies by Washburn

95

et al. (2011) and Aristizábal et al. (2016). The DRI has focused its efforts in many technical areas

96

including in-situ observations, coastal and ship board radar, satellite and aircraft remote sensing,

97

and numerical ocean modeling.

98

In an effort to gain some insight into this lightly observed region (Cudaback and McPhee-Shaw

99

2009; Dever and Winant 2002) off the California coast, to test equipment, and to test a newly

100

developed system of nested ocean models (Suanda et al. 2016), a pilot study was undertaken in the

101

summer of 2015 termed the Point Sal Innershelf EXperiment (PSIEX) pilot. The whole suite of

102

inner shelf DRI technical areas were at play during the pilot study, but of particular relevance to

103

this study were in situ measurements of temperature and current made between the 50 and 20 m

104

isobaths (Fig. 1, and Table 1)1 . Information concerning specific instrumentation on the moorings

105

and sampling schemes is also presented in Table 1.

106

The bottom topography is relatively simple between the 50 and 30 m isobaths but inshore of

107

this area the bottom becomes more rough and rocky. There is a rocky outcrop rising up to 15 m

108

water depth in the neighborhood of the O30 and O20 moorings. In the experimental region, current

109

and temperature variability is dominated by nonlinear internal wave activity, and Fig. 2 shows 1

In situ measurements were made all the way into the 8-m isobath, but the focus of this study is on deeper water.

7

110

examples of 4 different types of observed wave packets. By far the most common waves are waves

111

of depression bringing warm water down from the surface and these waves correspond to internal

112

tide bores (a), undular bores (b), and ISWs (c). The internal tide bore and undular bore are quite

113

similar except the undular bore has many high frequency ISWs near the front face of the bore. In

114

several cases the ISWs are separated from the bore and appear in groups (Fig. 2, Panel (c), yearday

115

205 to 205.2). In rarer cases, particularly in shallower depths, a reverse undular bore (d) is observed

116

in which the bore forms on the rear of the wave and solitary waves of elevation bring cold water up

F IG. 2117 from depth (Vlasenko and Hutter 2002; Duda et al. 2011). Table 1 118

One of the strongest observational limitations of the data set are the noisy ADCP currents.

119

Because of memory and power limitations, the ADCPs in this study sampled at a frequency of

120

1/5 Hz (one ping per 5 seconds) leading to smaller ensembles and some contamination by aliased

121

surface gravity wave processes such as wave groups, infra-gravity waves and/or aliasing by the

122

sea-swell band. While this noisiness is not important for the bores (due to their long timescale) it

123

severely limits the ISW analysis. In particular the often useful vertical velocities for examining

124

ISW dynamics(Richards et al. 2013) could not be used here. The temperature observations, on

125

the other hand, show the waves beautifully (Fig. 2), and since the T/S relationship in this region

126

is relatively simple (Fig. 3 and See (Dever and Winant 2002)) temperature is a good indicator of

127

vertical displacement. Because a consistent analysis procedure is sought for both bores and ISWs

128

it is most practical to carry out the analysis using temperature alone. But current information is

129

needed to derive energy fluxes and thereby examine dissipation processes. Through trial and error

130

it has been determined that it is more insightful and accurate to derive current information from a

131

displacement model using some approximations and kinematical constraints, than to work directly

132

with the noisy current data. One exception to this rule is that the observed currents were used to 8

133

validate and slightly correct the kinematic results for the bore horizontal velocities (See Sec. 4).

134

Lastly the mooring array provides critical information about the large-scale environment in

135

which the internal waves are propagating. Examples of low-pass filtered temporal variations in

136

background stratification and current fields are shown in Figs. 4 and 5. The cut off frequency for all

137

low-pass filtered data in this study is 0.25 cpd. A key result of this study is that stratification changes

138

are an important factor affecting the statistics of the internal waves. The stratification changes are

139

driven by winds (Lentz and Fewings 2012; Suanda et al. 2016) and by an active shelf eddy field

140

(Bassin et al. 2005) .

F IG. 3

F IG. 4 F IG. 5

3. Wave Analysis

141

The objectives of this section are two fold. First methods for wave detection and characterization

142

are described. This step involves two idealized but quite effective models with a few simple

143

parameters for match filtering in the time domain. The time domain approach is useful due to the

144

transient wave nature of the bores and ISWs as well as the strong variability from wave to wave.

145

Time domain techniques described here nicely complement harmonic methods which have had

146

broad use (Nash et al. 2005). The second more challenging goal is that of taking the models with

147

their fit parameters and inferring other properties of the waves such as speed, direction, energy

148

flux and propagation loss. This second step involves several reasonable assumptions that will be

149

discussed below and as such the derived wave quantities presented here should be considered to

150

be a zero or first order approximation to reality. Estimated uncertainties are at the 10% level. The

151

following sections provide an exposition of the adopted bore and ISW models and parameters as

152

well as details of the match filtering and parameter estimation problem. 9

a. Bore Model

153

154

A remarkably simple model represents the vast number of observed bores. Consider a mode 1, triangular waveform propagating in the x direction given by

ζ(x, z, t) = ζ0 ψ(z)(1 +

(x − x0 ) − c(t − t0 ) ), 0 < (x − x0 ) − c(t − t0 ) < ∆. ∆

(1)

155

Here the wave packet group speed is c, the on-set time of the bore is t0 , and ∆ is the bore spatial

156

width that can be related to the observed temporal width by

∆ = c∆t ,

(2)

157

assuming a wave of fixed form. The bore mode function is ψ(z) and is computed using the linear,

158

flat bottom, internal wave mode equation with rotation at the semi-diurnal frequency (Phillips 1977).

159

Low-pass filtered temperatures are used to estimate buoyancy frequencies which are then used

160

to compute the changing mode shapes over the course of the experiment (Fig. 4). The effects of

161

background currents on the mode shapes are ignored. The mode is also given a unit normalization

162

at the maximum value so that ζ0 is the displacement amplitude. Empirical Orthogonal Function

163

(EOF) analysis of the temperature and current records (not shown) supports the idea of a dominant

164

mode 1 vertical structure as is commonly observed (Helfrich and Melville 2006; Apel et al. 2007).

165

The objective is to fit this model locally to the moored observations by finding appropriate values

166

of ζ0 , t0 and ∆t . The details of the fitting procedure are described in Sec. 3c. The fit parameters

167

are thus a function of both time and mooring position. The issue of estimating the bore speed, c

168

as well as its direction has some complications. The approach here is to take bore onset times 10

169

at multiple moorings and use plane wave beamforming to estimate speed and direction. These

170

results are presented in Section 4.a, and the analysis reveals that the bores are primarily propagating

171

perpendicular to the isobaths and that their speed is given to a reasonable approximation by the

172

linear group speed, c0 , plus a first order KdV correction. The relation is 0

αζ0 3c0 ∫−D (ψ )3 dz c = c0 + , with α = 0 3 2 ∫−D (ψ ′ )2 dz ′

(3)

′

173

where D is water depth, ψ is the derivative of ψ, and α is the nonlinear parameter from the standard

174

KdV equation (Grimshaw et al. 2004; Apel et al. 2007).

175

Having fit the displacement model to the observations a practical way forward is to use kine-

176

matics to estimate the currents. Here again the assumption is that background currents are not

177

important but this is a complexity that may be relevant and will require further analysis (Grimshaw

178

et al. 2004; Helfrich and Melville 2006) . Ignoring advection, the vertical velocity is simply the time

179

derivative of the displacement and the horizontal velocity in the direction of the wave is obtained

180

via continuity (∂u/∂x = −∂w/∂z) yielding

w(x, z, t) = −

ζ0 cψ ∆

(4)

u(x, z, t) = ζ0 cψ [1 + ′

(x − x0 ) − c(t − t0 ) ]. ∆

(5)

181

Equation 5 slightly over estimates the observed u currents from the ADCPs where a factor of 0.8 is

182

needed to bring them into agreement (See Sec 4.c). Given this encouraging result it is tempting

183

to use the y−component of the momentum equation (∂v/∂t = −f u, the Coriolis parameter is f ) to

184

obtain the transverse current. This has been done but this model vastly over estimates the currents. 11

185

Furthermore the depth and temporal structure of the observed transverse currents is much more

186

complicated than the in-plane currents, a result that was reported by Lerczak et al. (2003). In the

187

foregoing analysis the transverse currents are therefore treated empirically based upon the ADCP

188

observations. This is discussed further in Sec. 4. In addition, there are of course issues with

189

discontinuities on the edges of this triangle wave but these effects will be ignored as second order.

190

Here also the x dependence has been retained but when these results are applied to a single mooring

191

this dependence is eliminated. In this case the maximum t − t0 = ∆t .

192

The notation and approach of Moum et al. (2007b,a) are by-and-large followed in defining the

193

wave energy quantities. Because transient wave events are being analyzed, the most fundamental

194

quantity is the wave energy transmitted per length of coastline, ⟨E⟩ (J/m). This quantity is the

195

vertically and horizontally integrated energy density, that is

⟨E⟩ = ∫

D 0

dz ∫

∞

−∞

E dx = ∫

0

D

dz ∫

∞ −∞

E cdt,

(6)

196

where the last step follows for a wave of fixed form. Here D is water depth and E is the wave

197

energy density, kinetic plus potential in the linear limit given by

ρ E = (N 2 ζ 2 + w2 + γu2 ). 2

(7)

198

In Eq.7, γ is an O(1) empirical factor derived from the ADCP observations that accounts for a slight

199

overestimate of u by the kinematic model and for the v contribution (See Sec. 4c, where we find

200

γ = 0.82 utilizing v = uf /σM 2 ). If an idealized sinusoidal mode shape with vertical wave number 12

201

π/D is used, the triangular bore model has a simple form for ⟨E⟩, namely

⟨E⟩ =

ρ0 2 2 N 2 ∆D D ∆ ζ0 c [ + + γπ 2 ], 2 2 3c 2∆ 3D

(8)

202

where N 2 is a water column average value of the squared buoyancy frequency. Here the order of

203

the terms correspond to potential energy, vertical kinetic energy, and horizontal kinetic energy. In

204

practice the integral over depth is done numerically with time dependent modes ψ(z) computed

205

using a time dependent buoyancy frequency profile. Equation 8 is useful for showing the dependence

206

on parameters, but it is not used directly in the analysis of the data. Because ∆ >> D for the bores

207

one can safely ignore the vertical kinetic energy contribution in this expression. This is not

208

necessarily so for the ISWs.

209

A transient energy flux (W/m) can be associated with the bore as follows

fE =

210

⟨E⟩ . ∆t

(9)

A second form of energy flux is useful for this analysis and that is a daily average flux given by

fE =

1 J ∑⟨E⟩j . T j=1

(10)

211

Here the energy of all the bores detected in a day (J) is summed up and then divided by the number

212

of seconds in a day (T = 86, 400 s). This second form of energy flux will be useful when examining

213

wave propagation loss. 13

b. ISW Model

214

215

Now considering the ISWs, there is a similarly simple and useful model that has the same parameters as the bore model. Here a mode 1 Gaussian waveform is used given by

ζ(x, z, t) = ζ0 ψ(z) exp[−

4((x − x0 ) − c(t − t0 ))2 ]. ∆2

(11)

216

As with the bores, EOF analysis reveals the expected dominant mode 1 structure for the ISWs

217

(Helfrich and Melville 2006; Apel et al. 2007). This Gaussian model is virtually identical to the

218

classic hyperbolic secant squared ISW solution of the KdV equation, but it should be noted that

219

in the present notation ∆ is the full width not the common half width of the ISW. The Gaussian

220

form is used instead of the hyperbolic secant due to its relative analytic simplicity for the quantities

221

of interest here. Here the ISW mode function, ψ(z), is computed using the linear, flat bottom,

222

non-rotating mode equation at a frequency that is one quarter of the maximum buoyancy frequency.

223

This choice of frequency means that rotation is not important and it yields mode shapes with either

224

no turning points or with turning points close to the boundaries. This vertical structure is consistent

225

with the observations as these mode shapes are fit to estimates of displacement as a function of depth

226

(Sec. 2.c). As with the bore model the fit parameters, ζ0 , t0 and ∆t are all functions of both time

227

and mooring position. The vertical and horizontal currents of the ISWs are obtained as described 14

228

previously for the bore model giving

w(x, z, t) =

4ζ0 cψ(z) 4((x − x0 ) − c(t − t0 ))2 2((x − x0 ) − c(t − t0 )) exp[− ][ ] ∆ ∆2 ∆

u(x, z, t) = −ζ0 cψ (z) exp[− ′

4((x − x0 ) − c(t − t0 ))2 ] ∆2

v(x, z, t) ≃ 0.

(12) (13) (14)

229

The out of plane current, v, is taken to be zero because rotation has a small effect on these high

230

frequency, small scale ISWs. As before with a mode vertical wave number of π/D, the wave energy

231

per length of coastline has a simple analytic form namely

ρ ⟨E⟩ = 2

√

π 2 2 N 2 ∆D 2D ∆ + ζ0 c [ + π2 ]. 2 8 2c ∆ 2D

(15)

232

Here the first, second and third terms correspond to potential energy, vertical kinetic energy, and

233

horizontal kinetic energy, and in practice the depth integral over the mode is done numerically using

234

the time dependent mode shapes computed as described above.

235

The transient wave energy flux and the daily average flux for the ISWs are of the same form

236

as that for the bores, namely Eqs. 9 and 10. This daily average flux is particularly important for

237

quantifying the ISW propagation loss because it is rarely possible to track a specific wave across

238

the moorings. Differences in daily average flux across shelf moorings then give a bulk measure of

239

the wave losses. 15

c. Signal Processing

240

Because of the similarity of the bore and ISW models, the processing steps are nearly identical

241

and therefore the exposition will be done together. The first step is the wave detection problem

242

which includes the estimation of the wave time t0 , the wave time width ∆t , and the wave temperature

243

amplitude, ∆T . Because temperature records are examined, the waves are most pronounced in the

244

main thermocline. The wave detection analysis, therefore is carried out for the second and third

245

sensor depths (Table 1), where the temperature records are band-pass filtered between 0.25 cpd

246

and 24 cpd for the bore problem and the records are high pass filtered with a cut-off frequency

247

of 24 cpd for the ISWs. The match filter is applied to the data as follows. At a given time tˆ0 a

248

Gauss-Markov estimation (Munk et al. 1995) (weighted least squares with priors) is carried out

249

on a small time span of data around tˆ0 to give a wave temperature amplitude ∆T , a temperature

250

offset, and a wave time width ∆t . The data time span for bore/ISW fits are ∆t and 2∆t . The fit

251

yields a normalized mean square model-data mismatch of χ2 (tˆ0 ). This procedure is repeated at

252

the next time step (30 seconds later) building up a timeseries of χ2 (tˆ0 ), ∆T (tˆ0 ), and ∆t (tˆ0 ). The

253

wave detection is then carried out by examining χ2 (tˆ0 ) and finding minima in which the model

254

accounts for over 50 percent of the data variance and where the temperature amplitude is positive

255

(waves of depression). The minima then give wave times t0 as well as ∆T (t0 ) and ∆t (t0 ). This

256

procedure is applied at the two sensor depths in the main thermocline as sometimes for various

257

reasons a detection is made at one depth but not the other. Examples of bore and ISW fits are shown

258

in Fig. 6, and examples of waves and detections in the across shore and along shore directions are

F IG. 6259 shown in Figs. 7 and 8. 260

Once the wave times and time widths are established then the Gauss-Markov fit is done over 16

261

all 5 sensors yielding a temperature amplitude as a function of depth, ∆T (t0 , z). Using low-pass

262

filtered temperature records, Tlp (t, z), where the cut-off frequency is 0.25 cpd, the temperature

263

amplitudes are converted to vertical displacement, ζ(t0 , z) using a nonlinear vertical interpolation

264

method2 . The last step is to estimate the mode 1 amplitude, ζ0 (t0 ). This is done by computing the

265

bore and ISW mode shapes from the low-pass filtered buoyancy frequency profiles (for example Fig.

266

4) as described above and then carrying out a least square fit to get ζ0 (t0 ). The depth fits are quite

267

good by virtue of the dominant mode 1 EOF structure of the waves (See discussion on limitations

268

below). Other quantities are also computed with the modes. The group speed, c0 (t0 ) and the KdV

269

nonlinear parameter α(t0 ) give an estimate of the wave speed, c(t0 ) via Eq. 3, and depth integrals

270

of ψ 2 , N 2 ψ 2 and (ψ )2 are used for the depth integrated energy flux. ′

271

A few words about the issues in carrying out this detection problem are necessary. The two

272

conjoined main issues are data model mismatch and detection probability vs false alarm. With

273

regards to data-model mismatch, Tables 2 and 3 show χ2 statistics and the simple match filter

274

models match 75-85% of the variability. It is important to point out that not all of the data/model

275

misfit is about shortcomings of the model. Some of the misfit is variability that is associated with

276

other processes that could not be filtered out. As for detection probability and false alarms, given

277

certain threshold choices in the detector one must accept some number of missed detections and

278

some number of false alarms. Via visual inspection we have chosen thresholds that capture nearly

279

all the obvious wave events but do let in a few dubious waves. There are also rare cases when the

280

model data mismatch is simply too severe to get a useful detection. The issue is not with the vertical

281

structure of the waves which is quite robust but with the temporal structure. For the bores three main 2

The method goes as follows. The perturbed temperature at sensor z is given by Tp (z) = Tlp (z) + ∆T (z). Using spline interpolation we then find the depth, zˆ, in the unperturbed profile where Tlp (ˆ z ) = Tp (z). The condition 0 ≤ zˆ ≤ D is enforced. The displacement is therefore ζ(z) = z − zˆ. This nonlinear method is more accurate than the linear method of using the local temperature gradient.

17

282

situations arise. The first is when there is an undular bore, which when lowpass filtered, gives a

283

bore on-set that is not as steep as a pure bore (Fig. 2). The second case is where the bore relaxation

284

is not a simple linear decrease. This occurs for flat-top looking bores or when a bore splits into two

285

bores perhaps due to nonlinear effects or wave interference. The third and last anomalous case is

286

that of the reverse undular bore (Fig. 2). Similarly for the ISW’s there are non-canonical looking

287

waves, which include square or flat-topped ISW’s perhaps due to strong non-linearity or a surface

288

mixed layer, closely spaced or interfering ISWs, “noisy” ISWs perhaps due to mixing processes,

289

and strongly surface intensified ISWs. As is evidenced by Figs. 7 and 8, the methods employed

290

here are capturing most of the variability, though it is clear from the previous discussion that we

F IG. 7291 cannot precisely close the error budgets with the present data set. F IG. 8 4. Statistics of Bores

292

Bore statistics are addressed first as the ISWs are in fact spawned from the bores. Summary

293

statistical information can be found in Table 2 for several observables. Because the bores are

294

generally identifiable from mooring to mooring the question of speed and direction of propagation

Table 295 2 can be directly addressed: This is not the case for the ISWs.

a. Speed and Direction

296

To estimate bore speed and propagation direction, plane wave beamforming was carried out

297

using the bore arrival times, t0 at four different moorings, two each on the 50 and 30 m isobaths.

298

The plane wave beamforming is implemented using the Gauss Markov method in this case to

299

estimate the two parameters from the four arrival times at the moorings. Because of nonlinearities 18

300

the approach is to linearize the problem and iterate a few times to get convergence. The initial

302

guess is c = 25 cm/s and propagation direction due East. The inversion is for the wave speed at the √ 50-m isobath and it is assumed that the speed has a D dependence. For the inversions both data

303

error covariance and prior covariances are assumed diagonal, and specific values are 1 hr2 for the

304

variance of t0 , 100 (cm/s)2 for the variance of c, and 400 deg2 for the variance in the direction. A

305

solution is considered acceptable if the data model residuals are all less than 1 hr which is the time

306

scale of the low-pass filter used in the bore detection.

301

307

An example using moorings S50, S30, LR50, and LR30 is provided in Fig. 9. Similar results are

308

obtained for other groups of moorings but this case is particularly insightful because of the relative

309

uniformity of the bottom slope along shelf. Here the observed wave speeds in Fig. 9 have been

310

corrected for large scale background currents. Low-pass filtered barotropic currents (e.g. See Fig. 5)

311

from the ADCPs at S50, S30, LR50, and LR30 were projected in the direction of wave propagation,

312

averaged and then subtracted from the estimated speed described above. This procedure, with

313

corrections ranging from -5 to +8 cm/s, significantly reduces the scatter in the estimated wave

314

speeds thus giving confidence in the result.

315

While there is some variability, the KdV corrected wave speeds computed using Eq. 3 show

316

a close correspondence to the observed speeds (Fig. 9). The wave speeds are also responding to

317

the changing stratification as exemplified by Fig. 4. For example there is a general speeding up of

318

the waves as the summer stratification strengthens. This result provides confidence in the use of

319

Eq. 3 for the calculation of energy fluxes. Note that time gaps in Fig. 9 occur where there are not 4

320

detections on each of the moorings or where there is large uncertainty in the bore time t0 . Note the

321

gaps around yeardays 176 and 210 are due to a strong drop in bore energy (See Sec. 4.c).

322

Lastly, the direction of bore propagation is slighly to the East-NorthEast (12○ from East) with 19

323

an rms of 10○ . Because of this result, it will be assumed in the subsequent analysis that the waves

F IG. 9324 are propagating perpendicular to the local isobaths.

b. Amplitude, Width, Separation, and Waves per Day

325

The mode 1 displacement amplitude, ζ0 , the wave time width, ∆t , the wave separation, ∆t0 , and

326

the number of waves per day, Nw have been characterized. Summary statistics are shown in Table 2.

327

The displacement amplitudes, ζ0 , are relatively large ranging from 1/5 to 1/2 the water depth thus

328

attesting to the energy and nonlinearity of these waves. The average bore time widths, ∆t , are close

329

to 9 hours and are thus shorter than the semi-diurnal tidal period again attesting to the nonlinearity

330

of the waves, and perhaps shoaling effects. While the bores themselves are shortened relative to the

331

tidal period, the interval between bores, ∆t0 is still close to the tidal period which is an indicator of

332

the regularity of the wave generation.

333

A key consideration is the along- and across-shelf variability. Along the 50-m and 30-m

334

isobaths the statistics of ζ0 and ∆t are relatively homogenous. The greatest inhomogeneity is in the

335

displacement statistics on the 30-m isobath where N30 is lower than the other three. This is due in

336

part to the fact that the distance between N50 and N30 is roughly 0.90 km longer than the distances

337

between the other lines (Table 1).

338

In the across-shelf direction the O-line (O50, O40, O30, and O20) is of primary interest. Here

339

the mean displacements show a steady decrease as the waves move onshore with a particularly

340

large drop from O30 to O20 where the bores are propagating over the rough rocky outcrop (Fig.

341

1). Regarding time width the trend is toward widening bores as the waves propagate onshore. This

342

suggests that dispersion is having an increasing effect on the bores as they weaken towards shore. 20

343

There is also the matter of number of bores per day, Nw and the bore separation, which are

344

shown in Table 2, columns 4 and 6. Here on average there are two bores per day, and roughly

345

on every other day there is a third bore. Also the average bore separation is between 11 and 12

346

hours with an rms of 3 to 5 hours (Table 2, column 6). The variability in the bore arrival times,

347

likely caused primarily by fluctuations in wave speed, can be associated with phase modulation of

348

the internal tide leading to a loss of coherence with the local tide. Colosi and Munk (2006) show

349

that the coherent and incoherent energy fractions are given by ν 2 and 1 − ν 2 respectively where

350

ν 2 = e−⟨θ ⟩ and ⟨θ2 ⟩ is the mean square phase. The observations suggest ⟨θ2 ⟩ ≃ 4 rad2 thus giving a

351

largely incoherent field (ν 2 = 0.0183).

2

c. Energy Flux

352

A key objective of the field work is to quantify internal wave energy fluxes and to come to an

353

understanding of the processes that are responsible for their variation. Candidate processes have

354

been discussed in Sec. 2. Before this is addressed, however, the matter of the bore transverse

355

currents needs to be confronted. A comparison between observed bore horizontal currents by

356

the ADCPs and modeled bore currents are shown in Fig. 10. Here the model is Eq. 5 and the

357

y−component of the linear momentum equation gives v, 2

ζ0 ∆f ψ (x − x0 ) − c(t − t0 ) v(x, z, t) = [1 + ]. 2 ∆ ′

(16)

358

In spite of bandpass filtering around the semi-diurnal tide frequency the ADCP currents are quite

359

noisy and so the important point here is not the scatter in Fig. 10 but the slopes. In the direction 21

360

of the wave, u, the observed and model currents are similar differing on average by a factor of

361

0.76 ± 0.02 (Fig. 10 ). At the 30-m isobath the factor is 0.81 ± 0.02. The transverse currents, v,

362

on the other hand , are dramatically over estimated by the model (Eq. 16), making this approach

363

for estimating the bore energy flux untenable. However, the observed ratio of u to v in the bore is

364

roughly what would be expected from a linear internal tide, that is the ratio f /σM 2 (Fig. 10 right

365

panels). A semi-empirical approach is therefore taken in computing the energy flux contributions

366

from the two components of the horizontal kinetic energy density, that is the u component of the

367

horizontal kinetic energy density is computed using the model and then it is multiplied by the factor

368 γ = (0.78)2 (1 + (f /σM 2 )2 ) ≃ 0.82 to give the total horizontal kinetic energy. F IG. 10

369

The mean and rms fluctuation of the bore energy density, ⟨E⟩, the individual wave transient

370

energy flux, fE , and the daily average energy flux f E are shown in Table 2. It is noteworthy that the

371

rms values are of the same order of magnitude as the mean values which will have some implications

372

for the physical interpretation of the variability in terms of interference.

373

The temporal evolution of the daily averaged energy fluxes f E averaged along the 50 and 30 m

374

isobaths are shown in Fig. 11. Variability over many timescales is observed. There is no apparent

375

correlation to the spring neap cycle where spring/neap tides are expected near yeardays 166/175,

376

184/190, 196/205, and 213/220 (See Fig 1). The lack of spring/neap modulation is perhaps due to

377

the 70 to 90 km propagation distance from the suspected generation region on Santa Rosa-Cortes

378

Ridge to the innershelf. Over this long distance propagation and dissipation mechanisms could be

379

masking the tidal modulation. Another possibility is that the internal tide is not generated locally

380

but remotely (Nash et al. 2012). There are also no correlations with the background currents (Fig.

F IG. 11 381 5). 382

There are however two events of strongly diminished fluxes between yeardays 175-182 and 22

383

206-212 that are associated with two periods of strongly reduced deep stratification (Figs. 11 and

384

4). The reduced fluxes are apparent in both the 50 and 30 m isobath records, but they are more

385

clearly observed at the 50 meter site. Recall that this result is observed along a 10-km along shelf

386

distance and so it is a large scale feature of the internal-wave field. The result could be due, in

387

part, to neap tides that occurred on year days 175 and 205 which immediately preceded the drop in

388

fluxes, but no similar drop in flux is observed during other neap tides. Another mechanism possibly

389

explaining the loss is the transfer of energy from the bores to the solitons. These two periods do in

390

fact correspond to times of increased soliton activity however the magnitude of the soliton fluxes

391

are not large enough to account for all of the drop in bore flux (See Section 5). Also there are

392

other times where the soliton activity is increased yet there is no corresponding drop in bore fluxes.

393

Another possibility is another form of dissipation, perhaps due to mixing or instability.

394

Two more promising possibilities are as follows. First there could be seaward/shoreward shifts

395

in the generation region thus increasing/decreasing the distance over which propagation loss can

396

act. Another interesting possibility is a change in wave amplification due to subcritical bottom

397

reflection, an effect that is sensitive to bottom stratification. The closer the bottom slope is to critical

398

the more forward reflecting amplification occurs. Using ray theory the wave intensity amplification

399

at frequency σ for one bottom bounce is sin(α + β) , sin(α − β)

400

(17)

where the subcritical group-propagation angle is α = tan−1 (σ 2 − f 2 )/(N 2 − σ 2 ) and the uniform

401

bottom slope is β. Bottom slopes on the Point Sal inner and mid-shelf are in fact just below critical

402

and fall in the range 0.4○ to 0.5○ . For bottom stratification variation from 6 to 3 cph, α changes 23

403

from 0.62○ to 1.23○ giving a variation in the amplification factor of 2-9. If there are multiple bottom

404

bounces involved the effects are multiplied. This is close to the factors needed to reconcile the low

405

frequency variations in bore flux shown in Fig. 11.

406

There is bore variability due to changes in the wave propagation environment but several factors

407

point to another critical factor and that is interference. In Table 2 the rms values of energy densities

408

and fluxes are comparable to the mean values. This is indicative of scintillation or strong interference

409

phenomena typical in many branches of wave propagation especially optics and acoustics (Colosi

410

2016). In these cases the probability density function (PDF) is telling (Fig. 12). The bore PDF of

411

energy flux resembles an exponential distribution. The physical interpretation of the exponential

412

PDF comes from the central limit theorem (CLT) where if we consider the field to be a sum

413

(interference) of many waves then the real and imaginary parts of the demodulated field tend

414

towards zero mean Gaussian random variables as the number of waves tends towards infinite(Colosi

415

and Baggeroer 2004). The PDF of intensity is then a degree 2 chi-square distribution or exponential,

416

and the PDF of wave amplitude is Rayleigh(Colosi 2016). The ratio of rms to mean for the Rayleigh

417

and exponential distributions are 0.52 and 1.0 respectively. These values are consistent with the

418

moments of displacement amplitude, ζ0 , and energy observables in Table 2. The energy flux PDF

419

for the ISWs is also reminiscent of an exponential (Section 5). Pinning down the source of the

420

interference in the bores will require further measurements but a little speculation is warranted.

421

First, it is possible that the interference is coming from multiple sources of internal tide or horizontal

422

plane propagation effects (Duda et al. 2014) . Another possibility is that the bore statistics are being

423

influenced by the ISWs because the majority of the bore events were undular bores that we attempt

424

to smooth out with low pass filters (Fig. 2).

425

In conclusion it is important to emphasize that the point of this PDF analysis is to show that the 24

426

observations have characteristics of interfering waves such as represented by the asymptotically

427

valid exponential PDF. Our objective is not to do a hypothesis test, though this has been done. The

428

Chi-square and Kolmogorov-Smirnov tests (Press et al. 1992) soundly reject the exponential PDF,

429

as is likely evident from the curves in Fig. 12.

F IG. 12

d. Propagation Loss F IG. 13

430

All measures of bore energy or flux are observed to decay as the bores propagate onshore (Table

431

2), and the objective here is to quantify and characterize this propagation loss. Because the bores are

432

propagating primarily perpendicular to the isobaths (Fig. 8), the wave propagation loss is defined as

433

a gradient of the daily average energy fluxes between the 50 and 30 m isobaths, that is

LE =

f E (50) − f E (30) . dx

(18)

434

The distances dx as a function of mooring pairs (N50/N30, O50/O30, etc) are given in Table 1.

435

A nearly linear relationship is obtained when the average flux between the 50 and 30 m isobaths,

436

f50,30 = (f E (50) + f E (30))/2 is plotted against the loss, LE (Fig. 13). This means that f E is

437

expected to decay exponentially with distance towards shore where a linear fit to the data yields

438

an e-folding scale of roughly xE = 2.4 ± 0.1 km. The exponential model also nicely represents the

439

changes in mean fluxes along the O-line from the 50 to 20 m isobaths (Fig. 13 right panel). The

440

decay rate is reasonable given that it is an average over all the 50 and 30 m isobath moorings.

441

The result that propagation loss is proportional to energy flux is not entirely unexpected since

442

higher amplitude waves are more prone to instability. The relation between propagation loss and 25

443

stratification is also of interest (Fig. 14). Here there is a slight tendency for the largest loss events to

444

be associated with larger N but otherwise the loss is mostly independent of N . Unfortunately the

445

field effort here did not have observations of turbulence and mixing, so the matter of bore dissipation

446

cannot be properly addressed. Subsequent field efforts in the main experiment will rectify this

447 situation. F IG. 14

e. Dissipation Rate

448

449

The exponential decay of the energy fluxes can also be interpreted in terms of a dissipation rate. Considering a 1-D balance, the wave energy equation is written

∂E ∂cE + = 0, ∂τ ∂x

(19)

450

where c is the group speed. Here it is important to distinguish between slow dissipation time τ

451

and fast transient wave time t. This scale separation is a bit flimsy for the bores but is much better

452

obeyed for the ISWs. Integrating Eq. 19 in both depth and time t an equation is obtained for the

453

transient wave radiated energy density, ⟨E⟩ that is ∂⟨E⟩ ∂⟨E⟩ +c = 0. ∂τ ∂x

(20)

454

Because of the way transient wave energy flux was defined (Eqs. 9 and 10) this means ⟨E⟩ will

455

also decay exponentially with propagation distance, and therefore the dissipation rate following the

456

wave is given by ∂⟨E⟩ ⟨E⟩(0) τ = exp[− ]. ∂τ τd τd 26

(21)

457

Here τd = xE /c is the dissipation timescale. At the 50-m isobath an average bore will have a

458

transmitted wave energy density ⟨E⟩ of about 2.3 MJ per meter of coastline, and τd ≃ 4.4 hours.

459

The initial dissipation rate is then about 144 W per meter of coastline, lessening as the wave moves

460

into shallower water. This large dissipation is a compelling observation in which the dissipated

461

wave energy could be going to turbulence or since we are seeing a gradient in the momentum flux

462

in the direction of the wave there could be a body force driving along shore flows via geostrophy

463

(Winters 2015). These are questions for future study.

5. Statistics of Internal Solitary Waves

464

The analysis of the ISWs is carried out along the same lines as that for the bores and of course

465

there is a dynamical connection here since the bores are the source of the ISWs. A summary of

466

several ISW statistical quantities is shown in Table 3.

a. Speed and Direction

467

Observationally establishing the speed and direction of the ISWs is problematic given the

468

variability of the waves and the array geometry. The plane wave beamforming carried out on the

469

bore arrivals cannot be done here because very rarely can an identifiable ISW be detected on two,

470

let alone four moorings in our array. Since the bores are spawning the ISWs its not an unreasonable

471

assumption that the ISWs are propagating in the same direction and roughly at the same speed

472

as the bores. This has been confirmed by a small number of identifiable ISWs. With regards to

473

ISW speed, there is some confidence in the KdV method (Eq. 3) which accurately re-produces the

474

observed bore speeds (Fig. 9). Therefore in the following analysis it is assumed that the waves are 27

Table 3

475

propagating perpendicular to the isobaths and that KdV theory is sufficient to estimate the wave

476

speeds. Calculations of the ISW speeds over the duration of the experiment shows a similar time

477

varying pattern to what was observed for the bores ( Fig. 9) except the ISW speeds are slightly

478

faster (Table 3). This last fact is supported by images of the undular bores (Figs. 2 and 7 ) which

479

shows the common occurrence of ISWs stretched out in front of the bores.

b. Amplitude, Width, Separation, and Waves per day

480

Four important ISW quantities that have been characterized are the ISW amplitude, the time

481

width, the time separation between successive waves, and the number of waves per day. ISW

482

displacement amplitudes are roughly one-third of those observed for the bores, but like the bores

483

the displacements have large variability with rms fluctuations of order half the mean (typical of the

484

Rayleigh distribution). The time widths also show a great deal of variability. In simple KDV theory

485

there is a relationship between displacement and width such that larger waves are narrower until a

486

maximal wave amplitude is reached after which the wave widens as the energy grows (Grimshaw

487

et al. 2004; Apel et al. 2007). However, in this analysis a not so simple relationship is found: small

488

narrow waves are just as likely to be found as large wide waves. The waves are also observed to be

489

relatively close to one another. The average wave separation is roughly 3 wave widths and there is

490

large variation about the mean. These three points: The large rms displacement relative to the mean,

491

the lack of a relationship between displacement and width, and the close proximity of the waves to

492

each other suggests that a nonlinear ISW interference pattern is being observed.

493

As with the bores a key consideration is the along- and across-shelf variability. Along the 50

494

and 30 m isobaths both displacement, time width, and time separation show relatively homogeneous 28

495

statistics (Table 3) which will allow for combining observations along isobaths to reduce sampling

496

errors. In the across shelf direction there is clear inhomogeneity. Vertical displacements are observed

497

to decay towards shore and the ISWs are narrowing in time width and time separation. More will be

498

said about the decay of the waves but the narrowing and changing time separation of the waves is a

499

topic that will likely need further analysis and modeling.

500

The number of ISWs in a day, Nw is another important observable, particularly with regards to

501

the amount of energy the ISWs transport over time. Not only does the displacement drop as the

502

waves move toward shore but also the number of ISW’s per day declines (Table 3). From the 50 to

503

20 m isobaths the rate of ISWs is reduced by a little over one half. The time evolution of ISW rate is

504

also of interest and is shown in Fig. 15. There is no correlation here with the spring/neap cycle but

505

there is correlation with the low frequency variations in shallow stratification as described below.

c. Energy Flux

506

Mean and rms fluctuation of the ISW energy density, ⟨E⟩, individual wave transient energy

507

flux, fE , and daily average energy flux f E are shown in Table 3. As in the case of the bores it

508

is noteworthy that the rms values are of the same order of magnitude as the mean values which

509

suggests interference. The discussion of the variability of the ISW’s however will start with an

510

examination of the temporal variability.

511

The temporal variation of ISW daily mean flux (f E ) for the 50 and 30 m isobaths are shown

512

in Fig. 16. This variation is compared to the low-frequency temporal changes of the maximum

513

stratification (depth mean N could be used too, but maximum N is chosen because the correlation

514

is a bit clearer). The timeseries show that peaks/valleys in the stratification are associated with 29

F IG. 15

515

peaks/valleys of the energy flux. Also, the fluctuations in daily average energy flux are largely

516

attributable to the fluctuations in the ISW rate (Fig. 15). To first order, N is the generation rate of

517

ISW’s from a bore, that is a new ISW is added to the undular bore every buoyancy period (Apel

518

2003). Variations in N are of order a factor of 2 while changes in ISW rate and energy flux are

519 much larger suggesting that there is slightly more afoot here than simply effects from N . F IG. 16

520

Daily average fluxes tell one story but these values are the average over many ISWs. The

521

individual ISW statistics show more variability and in all cases the rms fluctuation exceeds the mean

522

sometimes over a factor of 2. (Table 3). This is an indication of coherent interference yielding strong

523

focusing3 . The PDF of fE (Fig. 17) can be compared to the exponential and modulated exponential

524

distributions(Colosi et al. 2001b). The physical interpretation of the modulated exponential is of

525

random wave interference consistent with the exponential distribution but with some modulation

526

of the mean dictated by the parameter b . In this case an adequate comparison is obtained with

527

b = 0.45 which indicates that the mean is modulated by 45%. The notion that ISWs in the undular

528

bore or in packets of their own are interacting or interfering with each other is not new (Henyey and

529

Hoering 1997; Badiey et al. 2013, 2016). As previously noted the point of this analysis is not to do

530

a hypothesis test on any particular PDF model. The models simply demonstrate how interference

F IG. 17 531 and modulation effects can be manifest in the PDFs.

d. Propagation Loss

Next the issue of propagation loss is addressed. Like the bores, if LE is plotted against f50,30

532

3

An example of this phenomena of strong focusing are the bright bands/webs of light that can be observed on the bottom of a swimming pool as light passes through the wavy surface. Purely random interference does not create this pattern(Colosi 2016).

30

533

a linear relation is obtained (Fig. 18 left panel) but in this case the e-folding distance is slightly

534

shorter yielding xE = 2.0 ± 0.1 km. The exponential drop in mean energy flux across the O-line

535

demonstrates the effect (Fig. 18 right panel). The observation that more energetic waves have

536

greater loss was also reported by MacKinnon and Gregg (2003) and Shroyer et al. (2010). The

537

relationship between propagation loss and maximum N is shown in Fig. 14, and the result is similar

538

to the bore case. Some of the highest loss events are associated with large N , but for the majority of

539

the cases there is no clear relationship between loss and stratification.

e. Dissipation Rate

540

Dissipation rates for the ISWs are estimated using Eq. 21. Again thinking of the 50-m isobath

541

as a reference point, an average ISW will have a transmitted wave energy density ⟨E⟩ of about

542

20 kJ per meter of coastline, and τd ≃ 3.7 hours. The initial dissipation rate is then about 1.5 W

543

per meter of coastline, lessening as the wave moves into shallower water. This is less than the

544

dissipation rate for the bores (144 W/m) because of the smaller energy density. These values are

545

also much smaller than measurements made on the Oregon (14 W/m) and New Jersey (50 W/m)

546

shelves (Moum et al. 2007a; Shroyer et al. 2010). In both these cases wave dissipation was shown

547

to be roughly in balance with observations of turbulence dissipation.

6. Summary and Conclusions

548

Using some simple models and dynamical constraints, an effective time-domain methodology

549

has been developed to allow detection and characterization of over 1000 bore and 9000 ISW wave

550

events on the inner continental shelf off Point Sal CA over a 50 day period. This time domain 31

F IG. 18

551

approach is essential given the variable and transient nature of the waves. The spirit of the problem

552

is captured in the following question: How do you characterize a 12-hour wave that is different

553

every 12 hours?

554

Be that as it may, with the large ensemble of observed waves, the statistical behavior of several

555

nonlinear internal wave characteristics have been well quantified. Importantly statistical behavior

556

implies certain dynamics and two key results in this regard are 1) the observation of near exponential

557

PDFs for bore and ISW energy flux suggesting strong wave interference and 2) the observed linear

558

relationship between wave flux and propagation loss giving an exponential decrease in fluxes and

559

dissipation rates towards shore. A relevant point here is that there is no such thing as a typical wave,

560

rather it is the distribution functions of the waves that are of fundamental significance.

561

In this work an attempt was made to implicate certain dynamical processes driving the variability.

562

Here key issues are associated with the degree to which stratification changes, background flow

563

fields, and topographic effects initiated by processes such as up/downwelling, eddies, and the

564

coastal general circulation are modulating the waves. Dynamical processes of interest such as wave

565

instability and mixing, bottom reflection amplification, wave refraction and interference, nonlinear

566

wave-wave interaction, and transfer of energy from bores to ISWs may be working in isolation or

567

in concert. Understanding such processes is pre-requisite to making headway on other important

568

questions such as quantifying the transport of heat, salt, momentum, and other quantities in the

569

inner shelf, estimating novel stresses imposed on the large scale circulation by small scale processes,

570

and even for understanding acoustic propagation. But, more questions are raised than are answered,

571

and our data has limitations such that error budgets cannot be completely closed. Therefore new

572

modeling and observational efforts will be required to come to a dynamical understanding of the

573

observed wave distribution functions. 32

574

Acknowledgments:

575

funded under the inner shelf DRI. The authors are appreciative of the able captain and crew of the

576

R/V Oceanus for enabling the successful deployment and recovery of the instrumentation used in

577

this work. Special thanks to Jim Moum, and Tim Duda for enlightening discussions and helpful

578

comments on many versions of the paper.

This work was supported by the Office of Naval Research, and is

33

579

REFERENCES

580

Apel, J., M. Badiey, C. Chiu, S. Finnette, R. Headrick, J. Kemp, J. Lynch, A. Newhall, M. Orr,

581

B. Pasewark, D. Teilbuerger, A. Turgut, K. von der Heydt, and S. Wolf, 1997: An overview of

582

the 1995 swarm shallow water internal wave acoustic scattering experiment. IEEE J. Oceanic

583

Eng., 22, 465–500.

584

585

586

587

588

Apel, J., L. Ostrovsky, Y. A. Stepanyants, and J. Lynch, 2007: Internal solitons in the ocean and their effect on underwater sound’. J. Acoust. Soc. Am., 121(2), 695–722. Apel, J. R., 2003: A new analytical model for internal solitons in the ocean. J. Phys. Oc., 33, 2247–2269. Aristizábal, M. F., M. R. Fewings, and L. Washburn, 2016: Contrasting spatial patterns in the diurnal

589

and semidiurnal temperature variability in the santa barbara channel, california. J. Geophys. Res.

590

Oc., 121, 427–440.

591

592

593

594

Badiey, M., L. Wan, and J. Lynch, 2016: Statistics of nonlinear internal waves during the shallow water 2006 experiment. J. Atmos. Oc. Tech., 33, 839–846. Badiey, M., L. Wan, and A. Song, 2013: Three-dimensional mapping of evolving internal waves during the shallow water 2006 experiment. JASA Exp. Lett., 134.

595

Bassin, C., L. Washburn, M. Brzezinki, and E. McPhee-Shaw, 2005: Sub-mesoscale coastal eddies

596

observed by high frequency radar: A new mechanism for delivering nutrients to kelp forests in

597

the southern california bight. Geophys. Res. Let., 32, 12604–12607.

598

599

600

601

Brink, K. H., 1988: On the effect of bottom friction on internal waves. Cont. Shef Res., 8(4), 397–403. Colosi, J., 2016: Sound Propagation through the Stochastic Ocean. Cambridge University Press, 420 pp. 34

602

Colosi, J., R. Beardsley, J. Lynch, G. Gawarkiewicz, C. Chiu, and A. Scotti, 2001a: Observations

603

of nonlinear internal waves on the outer new england continental shelf during the summer

604

shelfbreak primer study. J. Geophys. Res. Oceans, 106(C5), 9587–9601.

605

Colosi, J., F. Tappert, and M. Dzieciuch, 2001b: Further analysis of intensity fluctuations from a

606

3252-km acoustic propagation experiment in the eastern north pacific ocean. J. Acoust. Soc. Am.,

607

110, 163–169.

608

609

610

611

612

613

Colosi, J. A., and A. B. Baggeroer, 2004: On the kinematics of broadband multipath scintillation and the approach to saturation. J. Acoust. Soc. Am., 116(6), 3515–3522. Colosi, J. A., and W. Munk, 2006: Tales of the venerable honolulu tide gauge. J. Phys. Oc., 36, 967–996. Cudaback, C. N., and E. McPhee-Shaw, 2009: Diurnal-period internal waves near point conception, california. Estuary, Coastal and Shelf Science, 83, 349–359.

614

Dever, E., and C. Winant, 2002: The evolution and depth structure of shelf and slope temperatures

615

and velocities during the 1997–1998 el nino near point conception, california. Progr. in Oc., 54,

616

77–103.

617

618

619

Duda, T., and D. Farmer, 1999: The 1998 whoi/ios/onr internal solitary wave workshop: Contributed papers. WOODS HOLE OCEANOGRAPHIC INSTITUTION Technical Report. Duda, T. F., Y. Lin, and B. Reeder, 2011: Observationally constrained modeling of sound in curved

620

ocean internal waves: Examination of deep ducting and surface ducting at short range. J. Acoust.

621

Soc. Am., 130, 1173–1187.

622

Duda, T. F., W. G. Zhang, K. R. Helfrich, A. E. Newhall, Y.-T. Lin, J. F. Lynch, P. Lermusiaux,

623

P. Haley, and J. Wilkin, 2014: Issues and progress in the prediction of ocean submesoscale

624

features and internal waves. 2014 Oceans-St. John’s, IEEE, 1–9. 35

625

626

627

628

629

630

631

632

633

634

635

636

637

638

Eriksen, C., 1998: Internal wave reflection and mixing at fieberling guyot. J. Geophys. Res., 103, 2977–2994. Grimshaw, R., E. Pelinovsky, T. Talipova, and A. Kurkin, 2004: Simulation of the transform of internal solitary waves on oceanic shelves. J. Phys. Oc., 34, 2774–2791. Helfrich, K. R., and W. K. Melville, 2006: Long nonlinear internal waves. Annu. Rev. Fluid Mech., 38, 395–425. Henyey, F. S., and A. Hoering, 1997: Energetics of borelike internal waves. J. Geophys. Res. Oc., 102, 3323–3330. Lamb, K. G., 2014: Internal wave breaking and dissipation mechanisms on the continental slope/shelf. Ann. Rev. Fl. Mech., 46, 231–254. Lee, C., and R. Beardsley, 1974: The generation of long nonlinear internal waves in a weakly stratified shear flow. J. Geophys. Res., 79(3), 453–462. Lentz, S., and M. Fewings, 2012: The wind- and wave- generated inner-shelf circulation. Annu. Rev. Mar. Sci., 4, 317?343.

639

Lerczak, J. A., C. Winant, and M. Hendershott, 2003: Observations of the semidiurnal internal tide

640

on the southern california slope and shelf. Journal of Geophysical Research: Oceans, 108.

641

Liu, A. K., 1988: Analysis of nonlinear internal waves in the new york bight. J. Geophys. Res. Oc.,

642

643

644

645

646

647

93, 12317–12329. MacKinnon, J., and M. Gregg, 2003: Mixing on the late-summer new england shelf-solibores, shear, and stratification. J. Phys. Oc., 33, 1476–1492. Moum, J., D. Farmer, E. Shroyer, W. Smyth, and L. Armi, 2007a: Dissipative losses in nonlinear internal waves propagating across the continental shelf. J. Phys. Oc., 37, 1989–1995. Moum, J., D. Farmer, W. Smyth, L. Armi, and S. Vagle, 2003: Structure and generation of turbulence 36

648

at interfaces strained by internal solitary waves propagating shoreward over the continental shelf.

649

J. Phys. Oc., 33, 2093–2112.

650

651

652

653

654

655

656

657

658

659

660

661

Moum, J. N., J. M. Klymak, J. D. Nash, A. Perlin, and W. D. Smyth, 2007b: Energy transport by nonlinear internal waves. J. Phys. Oc., 37(7), 1968–1988. Munk, W., P. Worcester, and C. Wunsch, 1995: Ocean Acoustic Tomography. Cambridge University Press, 433 pp. Nash, J., M. Alford, and E. Kunze, 2005: Estimating internal wave energy fluxes in the ocean. J. Atmos. and Oc. Tech., 22, 1551–1570. Nash, J. D., S. M. Kelly, E. L. Shroyer, J. N. Moum, and T. F. Duda, 2012: The unpredictable nature of internal tides on continental shelves. J. Phys. Oc., 42, 1981–2000. Phillips, O. M., 1977: The Dynamics of the Upper Ocean, 2nd edition. Cambridge University Press, 336 pp. Press, W. H., S. A. Teukolsky, W. T. Vetterling, and B. P. Flannery, 1992: Numerical Recipes in FORTRAN, Second Edition. Cambridge University Press.

662

Ramp, S. R., T. Y. Tang, T. F. Duda, J. F. Lynch, A. K. Liu, C.-S. Chiu, F. L. Bahr, H.-R. Kim, and

663

Y.-J. Yang, 2004: Internal solitons in the northeastern south china sea. part i: Sources and deep

664

water propagation. IEEE J. Oc. Eng., 29, 1157–1181.

665

Richards, C., D. Bourgault, P. S. Galbraith, A. Hay, and D. E. Kelley, 2013: Measurements of

666

shoaling internal waves and turbulence in an estuary. J. Geophys. Res.: Oceans, 118, 273–286.

667

Scotti, A., R. Beardsley, and B. Butman, 2006: On the interpretation of energy and energy fluxes of

668

nonlinear internal waves: An example from massachusetts bay. J. Fluid Mech., 561, 103–112.

669

Shroyer, E., J. Moum, and J. Nash, 2010: Energy transformations and dissipation of nonlinear

670

internal waves over new jersey’s continental shelf. Nonlinear processes in Geophysics, 17, 37

671

345–360.

672

— 2011: Nonlinear internal waves over new jersey’s continental shelf. J. Geophys. Res., 116(C3).

673

Suanda, S. H., N. Kumar, A. J. Miller, E. Di Lorenzo, K. Haas, D. Cai, C. A. Edwards, L. Washburn,

674

M. R. Fewings, R. Torres, and F. Feddersen, 2016: Wind relaxation and a coastal buoyant plume

675

north of pt. conception, ca: Observations, simulations, and scalings. J. Geophys. Res.: Oceans,

676

121, 7455–7475.

677

678

679

Vlasenko, V., and K. Hutter, 2002: Numerical experiments on the breaking of solitary internal waves over a slope-shelf topography. J. Phys. Oc., 32, 1779–1793. Walter, R. K., C. B. Woodson, P. R. Leary, and S. G. Monismith, 2014: Connecting wind-driven

680

upwelling and offshore stratification to nearshore internal bores and oxygen variability. J.

681

Geophys. Res. Oc., 119, 3517–3534.

682

Washburn, L., M. R. Fewings, C. Melton, and C. Gotschalk, 2011: The propagating response of

683

coastal circulation due to wind relaxations along the central california coast. J. Geophys. Res.

684

Oc., 116.

685

Wheelon, A. D., 2003: Electromagnetic Scintillation, Vols 1-3. Cambridge University Press.

686

Winters, K., 2015: Tidally-forced flow in a rotating, stratified, shoaling basin. Ocean Modelling, 90,

687

688

689

690

691

72–81. Wunsch, C., and R. Hendry, 1972: Array measurements of the bottom boundary layer and the internal wave field on the continental slope. Geophys. Fluid Dyn., 4, 101–145. Zhang, S., M. Alford, and J. Mickett, 2015: Characteristics, generation, and mass transport of nonlinear internal waves on the washington continental shelf. J. Geophys. Res. Oceans.

692

Zhang, W. G., T. F. Duda, and I. A. Udovydchenkov, 2014: Modeling and analysis of internal-tide

693

generation and beamlike onshore propagation in the vicinity of shelfbreak canyons. J. Phys. Oc., 38

694

44, 834–849.

39

695 696 697 698 699 700

Generated with ametsocjmk.cls. Written by J. M. Klymak mailto:[email protected] http://opg1.ucsd.edu/ jklymak/WorkTools.html

40

Tables Mooring S50 LR50 O50 N50 O40 S30 LR30 O30 N30 O20

Mean Depths (Temperature) (m)

Distance to Neighbors (km)

Location (Lat,Long)

6.2,16.5,26.4, 36.3,46.2 5.7,16.0,26.1,35.9,45.8 6.2,16.3,29.7,36.1,46.1 5.2,15.5,25.8,35.4,45.3 5.1,10.1,20.1,30.0,35.0 5.3,10.5,15.5,20.4,25.4 5.1,10.2,15.2,20.2,25.1 6.7,11.6,16.6,21.6,26.5 4.9,10.2,15.1,20.1,25.0 0.5,3,6,9,12,15,17,19∗

LR50: 3.05, S30: 3.05 O50: 3.43, LR30: 3.02 N50: 3.30, O40: 2.00 O50: 3.30, N30: 4.14 O50: 2.00, O30: 1.26 LR30: 3.08, S50: 3.05 O30: 2.76, LR50: 3.02 N30: 2.99, O40: 1.26 O30: 2.99, N50: 4.14 O30: 1.89

34.87946,-120.72643 34.90686,-120.72722 34.93755,-120.73135 34.96725,-120.73175 34.93410,-120.70975 34.87953,-120.69295 34.90726,-120.69403 34.93202,-120.69620 34.95798,-120.68776 34.92529,-120.67710

Table 1. Summary of moored temperature and current measurements for the PSIEX pilot. All moorings have complete records between 15 June and 6 August 2015 (yeardays 166-218), except O20 whose record runs from 09 June to 23 July 2015 (yeardays 160-204). On the 50, 40, and 30 meter moorings temperature measurements were made with SBE9 instruments (some with pressure) sampling every 30 seconds. On the 20 meter mooring temperature was measured using RBR instruments sampling at 1 Hz. Each location also had a nearby ADCP. The 300 kHz RDI ADCPs at these locations sampled at 12 pulses per minute with 2 m bins, except for the O20 location which had a 1000 kHz Nortek Aquadopp sampling at 1 Hz with 1-m bins. ∗ There were no pressure sensors on the O20 mooring so depths are nominal.

41

√ Events S50 LR50 O50 N50 O40 S30 LR30 O30 N30 O20 50m 30m

106 106 109 101 107 108 113 102 101 83 422 424

1 − χ2 0.78/0.18 0.75/0.20 0.74/0.19 0.78/0.17 0.73/0.22 0.80/0.15 0.79/0.17 0.78/0.18 0.74/0.21 0.64/0.25 0.76/0.18 0.78/ 0.18

Nw

ζ0 (m)

∆t0 ∗ (hrs)

∆t (hrs)

c (cm/s)

⟨E⟩ (MJ/m)

fE (W/m)

fE (W/m)

2.0/0.6 2.1/0.6 2.1/0.6 2.0/0.5 2.1/0.6 2.1/0.5 2.2/0.5 2.0/0.6 1.9/0.7 1.9/0.7 2.0/0.6 2.1/0.6

18/7.3 18/7.3 17/6.8 18/6.0 14/5.2 12/3.8 11/4.0 12/3.9 10/4.1 7.2/2.4 18/6.9 11/4

11.5/3.3 11.5/3.3 11.3/4.1 12.1/4.4 11.5/4.4 11.4/3.6 11.0/3.7 12.0/4.7 12.2/5.5 12.1/4.8 11.6/3.8 11.7/4.4

8.8/2.7 9.2/2.5 8.8/2.6 9.1/2.9 9.5/2.9 9.0/2.6 8.7/2.8 9.6/3.1 9.6/3.2 10/3.2 9.0/2.7 9.2/3.0

18/2.6 18/2.6 18/2.7 18/2.7 15/2.1 12/1.5 12/1.7 13/2.0 13/1.9 8.6/1.3 18/2.6 13/1.7

2.3/2.0 2.3/1.9 2.1/1.7 2.4/1.9 1.1/0.96 0.55/0.38 0.58/0.47 0.67/0.55 0.57/0.56 0.13/0.10 2.3/1.9 0.59/0.49

68/46 66/45 62/44 70/46 30/22 16/9.1 17/11 18/12 15/12 3.1/2.0 67/45 17/11

55/38 57/35 52/33 56/38 27/19 13/8.7 15/7.0 15/9.3 13/9.4 2.9/1.7 55/36 14/8.6

Table 2. Statistics of internal tide bores observed during the PSIEX pilot. In columns 3-11 the mean and root mean square (rms) fluctuation are shown in the format (mean/rms). The observables in columns 2-11 are, total number of bores detected, normalized rms temperature variability described by the bore model fit (1 is a perfect fit), number of bores per day, bore displacement amplitude, time separation between successive bores, bore time width, bore speed (Eq. 3), bore energy per length of coastline (Eq. 6), transient bore energy flux (Eq. 9), and daily average energy flux (Eq. 10). The last two rows are averages over the 50 and 30 m isobaths. ∗ We define ∆t0 as the time difference between successive bores.

42

√ Events S50 LR50 O50 N50 O40 S30 LR30 O30 N30 O20 50m 30m

1237 1088 1098 1219 907 941 735 750 754 478 4642 3180

1 − χ2 0.81/0.19 0.85/0.16 0.84/0.17 0.83/0.18 0.80/0.20 0.82/0.17 0.80/0.18 0.83/0.18 0.81/0.19 0.84/0.19 0.83/0.17 0.82/0.18

Nw

ζ0 (m)

∆t0 ∗ (min)

∆t (min)

c (cm/s)

⟨E⟩ (kJ/m)

fE (W/m)

fE (W/m)

23/14 22/12 21/14 24/14 17/14 18/15 14/12 14/10 15/9 12/9 22/15 15/12

7.3/4.8 6.9/4.7 7.3/4.8 7.0/4.4 5.7/3.5 5.1/3.0 4.6/2.6 5.1/2.9 4.7/2.8 2.1/1.5 7.1/4.7 4.7/2.8

23.1/13 23.9/13 22.8/13 24.0/13 22.1/13 20.3/13 20.3/13 20.8/13 22.0/13 18.3/12 23.5/13 20.9/13

7.6/3.9 8.2/3.9 8.2/3.8 8.3/3.8 7.6/3.9 6.5/3.4 6.6/4.0 6.8/3.8 7.1/3.6 5.6/3.5 8.1/3.8 6.7/3.7

19/2.7 19/2.6 19/2.4 19/2.5 15/2.1 14/1.9 13/1.7 13/1.6 14/1.4 8.1/1.1 19/2.6 14/1.6

20/38 19/36 22/42 20/33 8.1/13 4.4/6.4 3.8/5.8 4.4/6.5 4.3/6.8 0.29/0.48 20/37 4.2/6.4

40/63 36/57 40/64 38/57 17/24 11/14 9.1/13 10/14 9.8/13 0.84/1.3 39/61 10/13

5.5/4.3 4.9/3.9 5.2/5.0 5.5/4.7 1.6/1.6 0.90/0.90 0.62/0.78 0.72/0.72 0.74/0.75 0.038/0.029 5.3/4.5 0.75/0.80

Table 3. Statistics of internal solitary waves observed during the PSIEX pilot. In columns 3-11 the mean and root mean square (rms) fluctuation are shown in the format (mean/rms). The observables in columns 2-11 are, total number of ISWs detected, normalized rms temperature variability described by the ISW model fit (1 is a perfect fit), number of ISWs per day, ISW displacement amplitude, time separation between successive ISWs, ISW time width, ISW speed (Eq. 3), ISW energy per length of coastline (Eq. 6), transient ISW energy flux(Eq. 9), and daily average energy flux (Eq. 10). The last two rows are averages over the 50 and 30 m isobaths. ∗ We define ∆t0 as the time difference between successive ISWs in a wave packet, therefore only time differences less than 1 hour are considered in the statistics.

43

Figure Captions

F IG. 1. Experimental setting of the Point Sal region with mooring names and locations (red squares), and tide elevation at Port San Luis. Isobath contours start at 10 meters and increase in 5 meter increments to 55 meter. The most prominent topographic feature is the rocky outcrop between moorings O30 and O20. The across shelf transect, termed the O-line, is marked with a white line. For reference the distance between the S50 and N50 moorings is 9.8 km, the distance between S50 and S30 is 3.1 km, and the distance across the O-lines is 5.1 km. Between the 50 and 30 m isobaths the sea floor slope is slowly changing in the along shore direction and the slope has values roughly in the range 0.3 and 0.6 deg.

F IG. 2. Examples of four different types of nonlinear internal wave packets observed during PSIEX: (a) bore alone, (b) undular bore, (c) internal solitary waves, and (d) reverse undular bore. The reverse undular bore is the least common wave by far and is most likely observed in the shallowest water.

F IG. 3. Temperature and Salinity relationship for PSIEX (dots) derived from 10 CTD cats taken aboard the R/V Oceanus 6-10 August 2015. The continuous curve is a third order polynominal fit to the observations.

F IG. 4. Buoyancy frequency variability observed at the LR50 mooring which is a typical pattern observed at the other moorings. Buoyancy frequency profiles were computed from the low-pass filtered temperature records using a thermal expansion coefficient of 2.03 × 10−4 (1/○ C) from the equation of state with S=33.44 PSU, T=14 ○ C, and P=20 dbar. The thermal expansion coefficient translates the vertical temperature gradient into a potential density gradient. The cut off frequency is 0.25 cpd.

F IG. 5. An example of low pass filtered barotropic (a) and baroclinic (b) and (c) currents observed on the LR50 mooring which is a typical pattern observed at the other moorings. The cut off frequency is 0.25 cpd. At this mooring the u and v components of the current are approximately in the across/along isobath directions.

F IG. 6. Examples of bore (a) and ISW (b) fits for the O40 mooring. Observations are shown with solid lines and fits are shown with dash lines. 44

F IG. 7. Examples of bore and ISW detections on the O-line between the 50 and 20 m isobaths. Moorings O50, O40, O30, and O20 are depicted in panels (a), (b), (c), and (d). Green marks shows ISWs and red marks show bores. F IG. 8. Examples of bore and ISW detections along the 50 m isobath. Moorings N50, O50, LR50, and S50 are depicted in panels (a), (b), (c), and (d). Green marks shows ISWs and red marks show bores. F IG. 9. Planewave beamforming results for wave speed c (a) and direction (b) using bore arrival times, t0 at the 4 moorings S50, S30, LR50, and LR30. The observed wave speeds are corrected for background currents using low pass filtered barotropic currents projected in the direction of propagation and estimated using ADCP data from the 4 mooring locations. Theoretical estimates of wave speed at S50 and LR50 using the linear bore group speed plus the KdV correction (Eq. 3) are shown with plusses. Mean and root mean square (rms) fluctuation of the wave speed and direction are 20 and 6 cm/s and 12 and 10 degrees. Similar results are obtained for other mooring combinations. F IG. 10. Comparisons between observed and estimated/modeled mode 1 maximum bore currents at the 50 meter isobath (a) and (b). Also shown is the distribution of observed maximum u and v currents indicating the level of the momentum balance in the model (c), where it should be noted f /σM 2 = 0.59. The observed current is estimated from the ADCP data which is bandpass filtered between timescales of 3 and 20 hours. There is considerable scatter in the data giving R2 values for the three panels of 0.45, 0.20, and 0.35. Similar results are obtained at the 30-m isobath. F IG. 11. (a) Average buoyancy frequency at 45-m depth along the 50-m isobath, with labels for the Spring (S) and Neap (N) tides. Isobath averaged time series of bore daily average energy flux, f E , for the 50 m (b) and 30 m (c) isobaths. F IG. 12. Probability density function (PDF) of bore fE /⟨fE ⟩ averaged over the 50 and 30 m isobaths (Solid). The PDF is estimated from 846 observations of bore energy flux. For qualitative comparison purposes the exponential PDF indicative of wave interference is shown (dash). F IG. 13. (a) Average bore energy flux between the 50 and 30 m isobaths plotted against bore propagation loss LE . A straight line fit to the points yields a slope of 2.4±0.1 km (R2 = 0.83). A few points where the loss is negative have been excluded from the fit. (b) Mean daily average energy fluxes along the O-line (Table 2) are plotted with the exponential decay (dash) expected from the straight line fit in (a). The exponential curve at distance zero has a value of 55 W/m which 45

is the mean value on the 50-m isobath (Table 2). Errorbars represent the error in the mean given 20 independent samples. F IG. 14. A scatter plots of bore (a) and ISW (b) propagation loss LE vs maximum buoyancy frequency during the event. In rare cases there is negative loss meaning an increase in wave energy. F IG. 15. Timeseries of number of ISW events observed per day on the 50 meter (a) and 30 meter (b) isobaths. The spring/neap cycle is identified by the symbols S and N. F IG. 16. Maximum buoyancy frequency of the isobath averaged buoyancy frequency profiles on the 50 meter (a) and 30 meter (b) isobaths. Average time series of ISW f E on the 50 meter (c) and 30 meter (d) isobaths. The spring/neap cycle is identified by the symbols S and N. F IG. 17. Probability density function (PDF) of ISW fE /⟨fE ⟩ averaged over the 50 and 30 m isobaths (Solid). The PDF is estimated from 7822 observations of energy flux. For qualitative comparison purposes two model PDFs are shown, the exponential (dash) and the modulated exponential with b = 0.45 (dash-dot). F IG. 18. (a) Average ISW energy flux between the 50 and 30 m isobaths plotted against ISW propagation loss LE . A straight line fit to the points yields a slope of 2.0±0.1 km (R2 = 0.87). A few points where the loss is negative have been excluded from the fit. (b) Daily average energy fluxes along the O-line (Table 2) are plotted with the exponential decay (dash) expected from the straight line fit in (a). The exponential curve at distance zero has a value of 5.7 W/m which is the mean value on the 50-m isobath (Table 2). Errorbars represent the error in the mean given 20 independent samples.

46

Figures

F IG. 1. Experimental setting of the Point Sal region with mooring names and locations (red squares), and tide elevation at Port San Luis. Isobath contours start at 10 meters and increase in 5 meter increments to 55 meter. The most prominent topographic feature is the rocky outcrop between moorings O30 and O20. The across shelf transect, termed the O-line, is marked with a white line. For reference the distance between the S50 and N50 moorings is 9.8 km, the distance between S50 and S30 is 3.1 km, and the distance across the O-lines is 5.1 km. Between the 50 and 30 m isobaths the sea floor slope is slowly changing in the along shore direction and the slope has values roughly in the range 0.3 and 0.6 deg.

47

F IG. 2. Examples of four different types of nonlinear internal wave packets observed during PSIEX: (a) bore alone, (b) undular bore, (c) internal solitary waves, and (d) reverse undular bore. The reverse undular bore is the least common wave by far and is most likely observed in the shallowest water.

48

F IG. 3. Temperature and Salinity relationship for PSIEX (dots) derived from 10 CTD cats taken aboard the R/V Oceanus 6-10 August 2015. The continuous curve is a third order polynominal fit to the observations.

49

F IG. 4. Buoyancy frequency variability observed at the LR50 mooring which is a typical pattern observed at the other moorings. Buoyancy frequency profiles were computed from the low-pass filtered temperature records using a thermal expansion coefficient of 2.03 × 10−4 (1/○ C) from the equation of state with S=33.44 PSU, T=14 ○ C, and P=20 dbar. The thermal expansion coefficient translates the vertical temperature gradient into a potential density gradient. The cut off frequency is 0.25 cpd.

50

F IG. 5. An example of low pass filtered barotropic (a) and baroclinic (b) and (c) currents observed on the LR50 mooring which is a typical pattern observed at the other moorings. The cut off frequency is 0.25 cpd. At this mooring the u and v components of the current are approximately in the across/along isobath directions.

51

F IG. 6. Examples of bore (a) and ISW (b) fits for the O40 mooring. Observations are shown with solid lines and fits are shown with dash lines.

52

F IG. 7. Examples of bore and ISW detections on the O-line between the 50 and 20 m isobaths. Moorings O50, O40, O30, and O20 are depicted in panels (a), (b), (c), and (d). Green marks shows ISWs and red marks show bores.

53

F IG. 8. Examples of bore and ISW detections along the 50 m isobath. Moorings N50, O50, LR50, and S50 are depicted in panels (a), (b), (c), and (d). Green marks shows ISWs and red marks show bores.

54

F IG. 9. Planewave beamforming results for wave speed c (a) and direction (b) using bore arrival times, t0 at the 4 moorings S50, S30, LR50, and LR30. The observed wave speeds are corrected for background currents using low pass filtered barotropic currents projected in the direction of propagation and estimated using ADCP data from the 4 mooring locations. Theoretical estimates of wave speed at S50 and LR50 using the linear bore group speed plus the KdV correction (Eq. 3) are shown with plusses. Mean and root mean square (rms) fluctuation of the wave speed and direction are 20 and 6 cm/s and 12 and 10 degrees. Similar results are obtained for other mooring combinations.

55

F IG. 10. Comparisons between observed and estimated/modeled mode 1 maximum bore currents at the 50 meter isobath (a) and (b). Also shown is the distribution of observed maximum u and v currents indicating the level of the momentum balance in the model (c), where it should be noted f /σM 2 = 0.59. The observed current is estimated from the ADCP data which is bandpass filtered between timescales of 3 and 20 hours. There is considerable scatter in the data giving R2 values for the three panels of 0.45, 0.20, and 0.35. Similar results are obtained at the 30-m isobath.

56

F IG. 11. (a) Average buoyancy frequency at 45-m depth along the 50-m isobath, with labels for the Spring (S) and Neap (N) tides. Isobath averaged time series of bore daily average energy flux, f E , for the 50 m (b) and 30 m (c) isobaths.

57

F IG. 12. Probability density function (PDF) of bore fE /⟨fE ⟩ averaged over the 50 and 30 m isobaths (Solid). The PDF is estimated from 846 observations of bore energy flux. For qualitative comparison purposes the exponential PDF indicative of wave interference is shown (dash).

58

F IG. 13. (a) Average bore energy flux between the 50 and 30 m isobaths plotted against bore propagation loss LE . A straight line fit to the points yields a slope of 2.4±0.1 km (R2 = 0.83). A few points where the loss is negative have been excluded from the fit. (b) Mean daily average energy fluxes along the O-line (Table 2) are plotted with the exponential decay (dash) expected from the straight line fit in (a). The exponential curve at distance zero has a value of 55 W/m which is the mean value on the 50-m isobath (Table 2). Errorbars represent the error in the mean given 20 independent samples.

59

F IG. 14. A scatter plots of bore (a) and ISW (b) propagation loss LE vs maximum buoyancy frequency during the event. In rare cases there is negative loss meaning an increase in wave energy.

60

F IG. 15. Timeseries of number of ISW events observed per day on the 50 meter (a) and 30 meter (b) isobaths. The spring/neap cycle is identified by the symbols S and N.

61

F IG. 16. Maximum buoyancy frequency of the isobath averaged buoyancy frequency profiles on the 50 meter (a) and 30 meter (b) isobaths. Average time series of ISW f E on the 50 meter (c) and 30 meter (d) isobaths. The spring/neap cycle is identified by the symbols S and N.

62

F IG. 17. Probability density function (PDF) of ISW fE /⟨fE ⟩ averaged over the 50 and 30 m isobaths (Solid). The PDF is estimated from 7822 observations of energy flux. For qualitative comparison purposes two model PDFs are shown, the exponential (dash) and the modulated exponential with b = 0.45 (dash-dot).

63

F IG. 18. (a) Average ISW energy flux between the 50 and 30 m isobaths plotted against ISW propagation loss LE . A straight line fit to the points yields a slope of 2.0±0.1 km (R2 = 0.87). A few points where the loss is negative have been excluded from the fit. (b) Daily average energy fluxes along the O-line (Table 2) are plotted with the exponential decay (dash) expected from the straight line fit in (a). The exponential curve at distance zero has a value of 5.7 W/m which is the mean value on the 50-m isobath (Table 2). Errorbars represent the error in the mean given 20 independent samples.

64