Acoustic wave propagation in rivers: an experimental study

Geay, Thomas; Michel, Ludovic; Zanker, Sébastien; Rigby, James Robert

doi:https://doi.org/10.5194/esurf-7-537-2019

Articles | Volume 7, issue 2

https://doi.org/10.5194/esurf-7-537-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

https://doi.org/10.5194/esurf-7-537-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 7, issue 2

Research article

|

12 Jun 2019

Research article |

| 12 Jun 2019

Acoustic wave propagation in rivers: an experimental study

Thomas Geay, Ludovic Michel, Sébastien Zanker, and James Robert Rigby

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Final revised paper (published on 12 Jun 2019)
Supplement to the final revised paper
Preprint (discussion started on 12 Dec 2018)

Interactive discussion

Status: closed

AC: Author comment | RC: Referee comment | SC: Short comment | EC: Editor comment

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RC1: 'review of manuscript', Anonymous Referee #1, 25 Jan 2019
RC2: 'Interactive comment on “Acoustic wave propagation in rivers: an experimental study” by Thomas Geay et al.', Anonymous Referee #2, 01 Feb 2019
EC1: 'Editorial comment', Jens Turowski, 04 Feb 2019
AC1: 'First review of manuscript', Thomas GEAY, 28 Feb 2019

Peer-review completion

AR: Author's response | RR: Referee report | ED: Editor decision

AR by Thomas GEAY on behalf of the Authors (28 Feb 2019) Manuscript

ED: Referee Nomination & Report Request started (01 Mar 2019) by Jens Turowski

RR by Anonymous Referee #2 (12 Mar 2019)

RR by Anonymous Referee #1 (28 Mar 2019)

Suggestions for revision or reasons for rejection

The manuscript reports on underwater measurements of ambient acoustic noise levels collected in several shallow rivers in the French Alps. The rational for collecting the data is to improve the measurement of bedload gravel transport, by using passive underwater acoustic monitoring, of the sound radiated by inter-particle impacts of mobile material.

The authors have attended to the specific comments from the first review. As mentioned in the previous review all the results flow from the curve fitting to the data illustrated in figure 5. It is unclear whether the example shown in figure 5 for a 1.0 kHz band in the Leysse river is particularly representative of the whole data set. A figure 5 with subplots showing curve fitting for a number of frequencies would provide the reader with additional evidence of the approach. Further plots in an appendix for three of the rivers at different frequencies representing fits to low (Isere), medium (Leysse) and high (Arve) attenuation would be useful. Alternatively, the authors could make the data forming figure 5 available for all rivers and frequency bands as a supplement to the manuscript. This would allow other interested parties carry out similar analysis.

The data provided is of limited value for improving the detection of bedload transport acoustically owing to the substantial variability in riverine soundscapes. However, as mentioned in the previous review, there are limited studies of ambient acoustical noise levels in rivers and these data provide indicative background sound levels. The authors may be interested in other soundscape studies e.g. Vracar, M. S. and Mijic, M. Ambient noise in large rivers, J. Acoust. Soc. Am., 130, 1787–1791, 2011 and any other publications the authors can find for comparison and provide context for their own study.

The above suggestions are left to editorial discretion as to whether acceptance of the manuscript is contingent on the above additions.

Referee Report: PDF

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ED: Publish subject to minor revisions (review by editor) (02 Apr 2019) by Jens Turowski

AR by Thomas GEAY on behalf of the Authors (12 Apr 2019) Author's response Manuscript

ED: Publish subject to technical corrections (29 Apr 2019) by Jens Turowski

ED: Publish subject to technical corrections (14 May 2019) by Niels Hovius (Editor)

AR by Thomas GEAY on behalf of the Authors (22 May 2019) Author's response Manuscript

Short summary

This research has been conducted to develop the use of passive acoustic monitoring (PAM) for bedload monitoring in rivers. Monitored bedload acoustic signals depend on bedload characteristics (e.g., grain size distribution, fluxes) but are also affected by the environment in which the acoustic waves are propagated. This study focuses on the determination of propagation effects in rivers. An experimental approach has been conducted in several streams to estimate acoustic propagation laws.