Hegde, VS and Nayak, Shailesh and Huchchannavar, Girish K and Krishnaprasad, PA and Rajawat, AS and Shalini, G and Jayakumar, S and Gosavi, Kanchanagouri D
(2022)
Meso-scale foreshore evolution in low-energy, storm-dominated tropical west coast of India: Implications for shoreline management.
Journal of Earth System Science, 131.
ISSN 0973-774X
Full text not available from this repository.
| Abstract: |
Along the tropical coast, there is cyclic variation in wind, wave currents, water and sediment influx, and the coasts experience a monsoonal storm surge that reaches nearly 2–3 times higher than the rest of the year, and foreshores undergo a complex evolution during an annual cycle. Hence, knowledge of foreshore evolution is critical in shoreline management. In this paper, study results on meso-scale foreshore evolution in a low-energy headland bay beach, situated in the Central West Coast of India near Manki, are discussed based on their seasonal and decadal changes in sandy shoreline configuration, wave refraction, sediment movement and depositional process. Decadal changes in the shoreline configuration indicated headland-side erosion and bay growth whereas the southern end grown seawards between the period 1979 and 2001–2002, while the beaches adjacent to the creek present in the area showed accretion and farther south of the creek showed minor erosion, and the trend continued through 2015. Wave refraction patterns for the waves approaching from northwest (NW), west and southwest (SW) for the wave periods 6, 8, 10 and 12 s indicated (a) wave convergence at the central part of the Manki beach; for the waves approaching from NW for wave periods 6 s; (b) wave divergence for the waves approaching from west with wave periods 6, 8, 10 and 12 s and (c) wave convergence at the bay side for the SW as well as NW approach of waves for wave period 10 s. Seasonal beach modification, in general, indicated post-monsoonal to pre-monsoonal (September to April) accretion and May to September erosion. Foreshore is gentle and dissipative (<6°). Sediments in all the seasons are bimodal (at 2ϕ and 2.752ϕ) in nature, and show dominantly saltation to suspension mode of transport. A parabolic shoreline prediction model indicated negative sediment budget in the central and northern parts of the beach (near the headland) and positive sediment budget at the southern end of the beach. Integration of the foreshore profile, sediment movement pattern, results of parabolic shoreline prediction model and decadal changes in shoreline configuration indicated that sediment budget is a critical issue in headland-bounded beaches, and utmost care is needed in the management of such shore line. |
| Item Type: |
Journal Paper
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| Subjects: |
School of Natural and Engineering Sciences > Others |
| Divisions: |
Schools > Natural Sciences and Engineering |
| Date Deposited: |
20 Feb 2026 10:48 |
| Last Modified: |
20 Feb 2026 10:48 |
| Official URL: |
https://link.springer.com/article/10.1007/s12040-0... |
| Related URLs: |
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| Funders: |
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| Projects: |
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| DOI: |
https://doi.org/10.1007/s12040-021-01773-1 |
| URI: |
http://eprints.nias.res.in/id/eprint/3184 |
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