DSpace at VNU: Contribution of swash processes generated by low energy wind waves in the recovery of a beach impacted by extreme events: Nha Trang, Vietnam

Contribution of swash processes generated by low energy wind waves in the recovery of a beach impacted by extreme events: Nha Trang, Vietnam Authors: Jean-Pierre Lefebvre, Rafael Almar,

BioOne sees sustainable scholarly publishing as an inherently collaborative enterprise connecting authors, nonprofit publishers, academic institutions, research libraries, and research funders in the common goal of maximizing access to critical research

Contribution of swash processes generated by low energy wind waves in the recovery of a beach impacted by extreme events: Nha Trang, Vietnam

Author(s): Jean-Pierre Lefebvre, Rafael Almar, Nguyen T Viet, Dinh V Uu, Duong H Thuan, Le T Binh, Raimundo Ibaceta, Nguyen V Duc

Source: Journal of Coastal Research, 70(sp1):663-668.

Published By: Coastal Education and Research Foundation

DOI: http://dx.doi.org/10.2112/SI70-112.1

URL: http://www.bioone.org/doi/full/10.2112/SI70-112.1

BioOne ( www.bioone.org ) is a nonprofit, online aggregation of core research in the biological, ecological, and environmental sciences BioOne provides a sustainable online platform for over 170 journals and books published by nonprofit societies, associations, museums, institutions, and presses.

Your use of this PDF, the BioOne Web site, and all posted and associated content indicates your acceptance of BioOne’s Terms of Use, available at www.bioone.org/page/terms_of_use

Usage of BioOne content is strictly limited to personal, educational, and non-commercial use Commercial inquiries or rights and permissions requests should be directed to the individual publisher as copyright holder.

663 Contribution of the swash generated by low energy wind waves in the recovery process of a beach

Contribution of swash processes generated by low energy wind waves

in the recovery of a beach impacted by extreme events: Nha Trang,

Vietnam

Jean-Pierre Lefebvre†, Rafael Almar†, Nguyen T Viet‡, Dinh V Uu∞, Duong H Thuan‡, Le T Binh+,

Raimundo Ibaceta*, Nguyen V Duc@

†IRD-LEGOS

Université Paul

Sabatier/CNRS/CNES/IRD

Toulouse, France

jean-pierre.lefebvre@ird.fr

rafael.almar@ird.fr

‡ Water Resources University Faculty of Marine and Coastal Eng

Hanoi, Vietnam nguyentrungviet@wru.edu.vn duonghaithuan@gmail.com

∞ Hanoi University of Sciences

Departement of Oceanology Vietnam National University Hanoi, Vietnam

uudv50@gmail.com

+ Hydraulic Engineering Consultants

Hydrology and Environment Division

Hanoi, Vietnam

Lebinh.hec@gmail.com

*Universidad Técnica Federico Santa Maria, Valparaíso, Chile

raimundo.ibaceta@alumnos.usm.cl

@ Central Vietnam Construction and Consultancy, JSC

Vietnam nguyenvietducht1978@gmail.com

INTRODUCTION

Vietnam experiences a tropical monsoon climate, dominated

from April to September by southwest monsoons and from

October to late March or early April, by northeast monsoons

From May to November, central Vietnam is likely to be impacted

by tropical storms or typhoons, with possible events occurring

outside this period (Takahashi, 2011; Nguyen-Thiet al., 2012) In

2013, the site was impacted in October by typhoon Nari and in

November by super typhoon Haiyan Although regularly impacted

by these extreme events, the economy of Khanh Hoa province is

largely related to seaside tourism activities At present, the hotel

and catering industry is intensifying in the vicinity of the beach of

Nha Trang Although typically containing low energy, these short

(largely wind-) waves tend to counterbalance the result of

southward drift by a transport of sediment The swash zone likely plays a significant role in this recovery, due particularly to its infra-gravity oscillation (Masselink and Hugues, 1998; Butt and Russel, 2000)

Because of its shallow, turbulent and unsteady nature, measurements of the physical parameters in the swash zone using conventional data collection systems can be highly problematic

(Longo et al., 2002; Jackson et al., 2007; Gómez-Pujol et al.,

2011) Recently, various field studies involving increasingly complex experimental set-ups have been conducted (Blenkinsopp

et al., 2011; Almeida et al., 2013) More than a decade ago,

different techniques taking advantage of video have been proposed

(Holman et al., 1993; Foote and Horn, 1999; Holland et al., 2001; Vousdoukas et al., 2014)

The present paper provides a description of the first of two field experiments scheduled before and after the cyclonic season, one

ABSTRACT

Lefebvre, J.-P., Almar, R., Viet, N.T., Uu, D.V., Thuan, D.H., Binh, L.T., Ibaceta, R., Duc,N.V., 2014 Contribution of swash processes generated by low energy wind waves in the recovery of a beach impacted by extreme events: Nha

Trang, Vietnam In: Green, A.N and Cooper, J.A.G (eds.), Proceedings 13 th International Coastal Symposium

(Durban, South Africa), Journal of Coastal Research, Special Issue No 70, pp 663-668, ISSN 0749-0208

Nha Trang beach experiences southerly sediment drift during winter monsoons and northerly sediment drift during summer monsoons In addition, the area is likely to be impacted by tropical storms or typhoons Due to the presence of islands at the south east border of the bay, the strongest impact on the shoreline apart from extreme events is due to NE swell from October to April The mechanism responsible for the sediment drift generated by low energetic locally generated wind waves is insufficiently understood It involves the functioning of the swash zone for weak conditions Two field experiments were scheduled before and after the period of cyclonic activity The aim of the first experiment was to describe the site’s bathymetry and the geomorphology of the upper beach and hydrologic functioning of the bay

A new method of measurements in the swash and surf zone based on processing of data extracted from HD video processing was tested successfully for wind wave conditions in a reflective beach Here, we present some data obtained during the field experiment at different time scales The data provides a first quantification of the impact on sediment transport from typical low energy conditions which are encountered during spring and summer in Nha Trang

ADDITIONAL INDEX WORDS: swash zone, surf zone, low energetic waves regime, video processing, typhoon

www.JCRonline.org

www.cerf-jcr.org

DOI: 10.2112/SI70-112.1 received 30 November 2013; accepted 21

February 2014 © Coastal Education & Research Foundation 2014

664 Lefebvre et al

during the summer monsoon, the other during the winter

monsoon In order to investigate the role of the swash zone in the

recovery phases generated by low energy waves, different

techniques were used to collect data at different time scales (swash

event scale, tide scale and month scale) A new method based on

video monitoring of swash and surf zone was also tested for low

energetic, high-frequency conditions

METHODS Site presentation

A field experiment was conducted from 26th to 30th May, 2013

in Nha Trang, Vietnam facing the China Sea Located in a

semi-enclosed bay, the beach of Nha Trang (12°15'N–109°11'E) is

sheltered from SE winds and waves by Tre, Mieu and Tam

islands Apart from extreme events, the beach is impacted by

waves generated locally by moderate south-eastern winds and by

north-eastern swells responsible for a strong southward longshore

sediment drift The beach is about 7 km long, oriented

South-North and composed by medium sand (φ = 2) The average slope

in the swash zone is of approximately 6°, and approximately 3° in

the surf zone The tide is of micro-tidal varying from mixed to

diurnal

DATA Instruments and Measurements

A suite of instruments were deployed along a cross-shore transect from beyond the depth of closure to the swash zone (Figure 2) The incident wave parameters were measured by two AWACs (Nortek) moored together with two grain size analyzers (LISST-25X, Sequoia Scientific, Inc) at depth 7.0 and 9.2m, respectively A pressure type wave gauge DNW-5M and a multi-parameter sensor: water height, wave height and period, turbidity) (OBS-3A, OSIL), both coupled with an electromagnetic current meter (COMPACT) were moored at depth 4.8m and 2.6m, respectively Measurement of the bathymetry of the bay was achieved with a dual frequency echo-sounder during the first day

of the field experiment Daily topographic measurements of the beach were conducted with a theodolite (Topcon, GTP101) and differential GPS The experimental setting was completed by an alignment of 20 black painted metallic poles each with a 30mm wide red tape adhered near their tops They were deployed cross-shore from the backcross-shore toward the surf zone; the 13 landward-most poles were spaced one meter apart and the last 7, two meters apart The actual position and elevation of the top of each pole was measured with a theodolite A high definition video camera (HDR-CX 250, Sony) was used to monitor the waves along the poles over daylight hours with an acquisition rate of 25Hz A micro-profiler ADV (Vectrino II, Nortek) was deployed in the vicinity of the poles, at either end of the surf zone or at the highest point of the run up, following the tide-induced displacement of the swash zone Topographic surveys were carried out three times a day with a theodolite from the backshore up to approximately 1.5

meter depth During two days, hourly surveys of the elevation of

the bed at each pole, was conducted by manually measuring the elevation between the top and the base of each pole This pole-related measurement was referenced with the three-dimensional position of the top of the pole

A permanent video station made up of two video cameras (IP7361 Vivotek) deployed on the same lamp-post, one pointing

to the North, the other installed before the field experiment This system allows a real time evaluation of changes in the intertidal bed elevation The description of the system and image

processing are detailed in Almar et al (2014) The bed elevation

of the intertidal domain is obtained by plotting the averaged water line

Figure 2 Experimental setup Left: AWAC and LISST 25X (B), pressure sensor and electromagnetic current meter (C), multi-parameters sensor OBS-3A (D), poles and micro-profiler ADV (E) Right: photo of alignment of poles and the ADV micro-profiler Figure 1 Nha Trang bay Site of experiment is circled in red

Contribution of the swash generated by low energy wind waves in the recovery process of a beach 665

Video processing

The wave height in the swash and surf zone simultaneously at

each pole was obtained at a sample rate of 25Hz using an

unsupervised method In each frame of a video recording of 250s

duration, the red, green and blue component of the pixels located

on lines passing along each pole are extracted and stacked into a

matrix The red component is used to detect the width of the tape

and to calculate the pixel to mm conversion factor for a given

pole

In order to minimize the influence of variation of ambient light,

uncertainty between water with suspended sediment and bed,

variation of bed color with saturation, shadow and reflection of the

pole on wet sand amongst other sources of perturbation, the stacks

are normalized and enhanced in hue and intensity First, the

intensity of each red, green and blue raster is maximized

separately The stack is then converted in Hue-Saturation-Value

coding and the ochre to red band corresponding to the sediment

color is enhanced A binary mask is obtained and the smallest gaps

are filled This mask is finally applied to the enhanced stack which

reduces the noise in the final stack and enhances the transitions

between water and pole (Figure 3) The water level is obtained by

detection of dark /light transition in the blue raster of the enhanced

stack The wave spectral density is calculated from the temporal

water level The bed is estimated by statistical analysis of the time

variations of detected water level In order to limit the influence of

uncertainty of the method, only emerged episodes of more than

one second are considered, and locations with at least 1/20 of time

emerged are considered as in the swash zone

PRELIMINARY RESULTS

The field experiment was carried out from neap to neap tide,

with a tide range varying from 1.2 to 1.8m The waves originated

mostly from the SE with a mean height of approximately 0.2m

(Figure 4)

The wave spectral density obtained from the processing of

sequences of 250s of swash-surf video indicated a rapid

dissipation of 75% of the wave power at the transition between the

surf zone to the swash zone (Figure 5) and a peak period of 2.7s

which is consistent with the measurements by the AWACs

(2.15s) A group period of 20s was observed in the upper swash zone At the upper part of the swash zone, the bed evolution showed an accretion at the rate of 0.04mm s-1 (Figure 6)

The hourly monitoring of bed elevation measured manually at the eleven first poles of the alignment (swash and surf zone) during an ebb tide (29/05 - tide range 1.47m) and a rising tide (30/09 - tide range 1.36m) is presented in figure 4, the distance between poles measured from the most landward one During the two days, the waves originated from the ESE with a mean height and period of 0.30m and 3s, respectively, the 29/05 and 0.19m and 6s, the 30/05

At the beginning of ebb tide, the upper swash zone was accreting (from reference to 3.9m seaward) and the surf zone was eroding After mid-tide, (tide elevation of 0.3m) a significant accretion was noted in the surf zone (poles between 7m to 8.9m seaward from reference) At the end of ebb tide, an accretion was measured at every emerged pole During 8 hours of the ebb tide, the 10m portion comprising the swash zone and a part of the surf zone accreted at the rate of 0.8cm m-2 h-1 (Figure 7)

Figure 3 Normalization-enhancement of timestack Initial

timestack (a) RGB intensity normalized stack (b) Mask obtained

by selection of ochre-red color band (c) enhanced stack obtained

by masking of the RGB intensity normalized stack (d)

Figure 4 Mean height in meters of waves measured at B during the field experience (left) and percentage of occurrence

of the wave from a given direction (right)

Figure 5 Decay of wave spectral density at the boundary between surf zone and swash zone (red) The bed elevation is represented in blue with the circle indicating the position of the poles 5 to 9 (from left to right) The dashed line marks the tidal height at the moment of the measurement

666 Lefebvre et al

Figure 6 Monitoring of variation of bed elevation in the swash- surf zone from pole #5 to #9 (top to bottom) The water height detection is plotted on the timestack in yellow and the detected bed in red (centre) The corresponding water spectral density is shown with bed elevation (for pole located in the swash zone) (left)

Contribution of the swash generated by low energy wind waves in the recovery process of a beach 667

From the video survey system, we extracted at a different date,

the bed elevation in the intertidal zone along a cross-shore line

close to the field experiment (Figure 8) The area was accreting

from May to October After 12th October, significant erosion

occurred, probably due to the North-East wave regime associated

with winter monsoons In the night of 13th and 14th October, Nha

Trang experienced strong waves associated with the passage of

typhoon Nari The effect of this event caused an accretion that counter-balanced the erosion generated by the NE swell of the winter monsoon During the night of 10th and 11th November, Nha Trang beach was impacted by waves generated by the passage of super typhoon Haiyan (Figure 9)

DISCUSSION AND CONCLUSIONS

During the first field experiment of our two-year project, the hydrodynamics of the site was described both by conventional techniques (mooring of wave gauges and current meters, bathymetry and topography surveys) and by less usual and low cost methods (video survey of the beach, high frequency monitoring of swash and surf zone) The processing of information extracted from surveys allows a quantification of variation of bed elevation of the intertidal domain, in a radius of approximately 1 km around the video survey station The setting successfully resisted to two major tropical storms induced by the passage of typhoons Nari and Haiyan

The measurements of bore propagation in the swash and surf zones by video acquisition of poles proved to be efficient It provided consistent wave spectral density for location spaced every meter The water height was detected precisely enough to allow a wave to wave analysis of the run up and run down The simultaneity of measurements at different locations is inherent to the method The bed can be detected even between short laps between a run up and run down events The field experiment confirmed the sediment transport landward due to the swash generated by weak wave Finally, the asymmetry of sediment transport in the surf and swash zone for the rising and ebb tide during similar wave conditions was shown

ACKNOWLEDGEMENT

The work described in this publication was supported by the Vietnamese Ministry for Science and Technology (BKHCN/NDT-HD/2013/110) We thank the National Institute of Oceanography

of Nha Trang for its help in the preparation and carrying out of this field experiment

Figure 7 Monitoring of variation of bed elevation in the swash-

surf zone

Figure 8 Bed elevation of the inter-tidal domain estimated by processing of images from the video survey (left) trajectory of typhoon Nari (right)

668 Lefebvre et al

LITERATURE CITED

Almeida, L.P., Masselink G., Russell, P., Davidson, M., Poate, T.,

McCall, R., Blenkinsopp, C., Turner, I., 2013 Observations of

the swash zone on a gravel beach during a storm using a

laser-scanner (Lidar) Journal of Coastal Research, Special Issue No

65, 636–641

Almar, R., Hounkonnou, N., Anthony, E., Castelle, B., Senechal,

N., Laibi, R., Mensah-Senoo, T., Degbe, G., Quenum, M.,

Dorel, M., Chuchla, R., Lefebvre, J-P, du Penhoat, Y., Laryea,

W.S., Zodehougan, G., Sohou, Z., and Appeaning Addo, K., and

Kestenare, E., 2014 The Grand Popo beach 2013 experiment,

Benin, West Africa: from short timescale processes to their

integrated impact over long-term coastal evolution In: Green,

A.N and Cooper, J.A.G (eds.), Proceedings 13th International

Coastal Symposium (Durban, South Africa), Journal of Coastal

Research, Special Issue No 66

Baldock, T.E., Hughes M.G., 2006 Field observations of

instantaneous water slopes and horizontal pressure gradients in

the swash-zone Continental Shelf Research, 26, 574–588

Blenkinsopp, C.E., Turner, I.L., Masselink, G., Russell, P.E.,

2011 Swash zone sediment fluxes: Field observations Coastal

Engineering, 58, 28–44

Butt, T., Russel, P., 2000 Hydrodynamics and Cross-Shore

Sediment Transport in the Swash-Zone of Natural Beaches: A

Review Journal of Coastal Research, 16, 2, 255–268

Foote, M., Horn, D., 1999 Video measurement of swash zone

hydrodynamics Geomorphology, 29, 59–76 Holland, K.T.,

Puleo, J.A., Kooney, T.N., 2001.Quantification of swash flows

using video-based particle image velocimetry Coastal

Engineering, 44, 65–77

Gómez-Pujol, Luis, Jackson, Derek, Cooper, Andrew, Malvarez, Gonzalo, Navas, Fatima, Loureiro, Carlos and Smyth, Thomas,

2011 Spatial and temporal patterns of sediment activation depth

on a high-energy microtidal beach Journal of Coastal Research,

SI 64 pp 85-89

Holman, R.A., Sallenger, Jr., A.H., Lippmann, T.C., Haines, J.W.,

1993 The application of video image processing to the study of nearshore processes Oceanography, 6(3), 18–85

Jackson, D.W.T., Anfuso, G and Lynch, K., 2007 Swash bar dynamics on a high-energy mesotidal beach Journal of Coastal

Research, SI 50 pp 738-745

Longo, S., Petti, M., Losada, I.J., 2002 Turbulence in the swash

and surf zones: a review Coastal Engineering, 45, 129–147

Masselink, G., Hugues, M., 1998 Field investigation of sediment

transport in the swash zone Continental Shelf Research,18,

1179–1199

Nguyen-Thi, H.A., Matsumoto, J., Ngo-Duc, T., Endo, N., 2012 Long-term trends in tropical cyclone rainfall in Vietnam Journal

of Agroforestry and Environment, 6(2), 89–92

Takahashi, H.G., 2011 Long-term changes in rainfall and tropical

cyclone activity over South and Southeast Asia Advances in

Geosciences, 30, 17–22

Vousdoukas, M.I., Kirupakaramoorthy, T., Oumeraci, H., de la Torre, M., Wübbold, F., Wagner, B., Schimmels, S., 2014 The role of combined laser scanning and video techniques in

monitoring wave-by-wave swash zone processes Coastal

Engineering, 83, 150–165

Figure 9 Monitoring of the location of field experiment: left: before and after typhon Nari (13 October): 12/10(a), 14/10 (b), 16/10(c) and 18/10 (d) and right: before and after typhoon Haiyan (10 November): 9/11 (e), 10/11 (f), 11/11(g) and 12/11 (h)