Fluvio-hydrological characteristics and diverse bedrock geology control the dynamic growth, truncation, and amalgamation of bedrock streambed and marine potholes

Biswajit Bera , Sumana Bhattacharjee , Uttam Mukhopadhyay , Debasis Sengupta , Pravat Kumar Shit , Nairita Sengupta , Supriya Ghosh , Arijit Ghosh , Soumik Saha , Sudipa Sarkar

River ›› 2025, Vol. 4 ›› Issue (1) : 84 -105.

PDF (8119KB)
River ›› 2025, Vol. 4 ›› Issue (1) : 84 -105. DOI: 10.1002/rvr2.117
RESEARCH ARTICLE

Fluvio-hydrological characteristics and diverse bedrock geology control the dynamic growth, truncation, and amalgamation of bedrock streambed and marine potholes

Author information +
History +
PDF (8119KB)

Abstract

A total of 393 potholes (368 fluvial and 25 marine potholes) were studied at seven different sites in both the fluvial and marine environments. Diverse bedrock properties and large-scale delivery of tools and grinders regulate the dynamic growth, truncation, and amalgamation of potholes. Therefore, the principal objectives of the study are (i) to examine the relationship between the growth of potholes and substrate lithological with structural characteristics (applying geospatial and Schmidt hammer for rock strength analysis) and (ii) to measure the morphology, and size of tools and grinders, processes of truncation and amalgamation in hydro-geomorphic environment using various indices and field techniques. The result showed that large potholes are stretched in the direction of lineament axes and roughly parallel to the river flow direction. Here, the steady growth of pothole depth-diameter is controlled by active bedrock structures, tools, or grinders, and monsoonal high-velocity bank full discharge. Consequently, the deepening and widening of potholes are relatively slow at Bindu, Deuli, and marine beach Neil Island due to fewer structures and little supply of tools or grinders. In small stretches, (Damodar, Subarnarekha, and Rarhu) canyons and gorge-like features (bedrock incision) are formed at Rajrappa, Bhakuyadi, and Guridih sites due to cyclic truncation and amalgamation. Truncation and amalgamation processes restrict the vertical depth threshold value of potholes within 3m, particularly at Rajrappa, Bhakuyadi, and Guridih sites. Scientific study of the pothole’s dynamic growth is greatly necessary for the different environmental engineering and river hydraulic projects like excavation, dredging, and dam or barrage construction. Successively, it is essential to compute the cost of rock excavation or dredging, primarily for the mechanical strength of the bedrock river channel and its stability.

Keywords

bedrock structures / rock strength / Schmidt hammer rebound values / toolsand grinders / truncation and amalgamation

Cite this article

Download citation ▾
Biswajit Bera, Sumana Bhattacharjee, Uttam Mukhopadhyay, Debasis Sengupta, Pravat Kumar Shit, Nairita Sengupta, Supriya Ghosh, Arijit Ghosh, Soumik Saha, Sudipa Sarkar. Fluvio-hydrological characteristics and diverse bedrock geology control the dynamic growth, truncation, and amalgamation of bedrock streambed and marine potholes. River, 2025, 4(1): 84-105 DOI:10.1002/rvr2.117

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Alexander, H. S. (1932). Pothole erosion. The Journal of Geology, 40 (4), 305–337.

[2]

Allen, J. R. L. (1968). The nature and origin of bed-form hierarchies. Sedimentology, 10 (3), 161–182.

[3]

Allen, J. R. L. (1971). Bed forms due to mass transfer in turbulent flows: A kaleidoscope of phenomena. Journal of Fluid Mechanics, 49 (1), 49–63.

[4]

Bera, B., Bhattacharjee, S., Chamling, M., Ghosh, A., Sengutpa, N., & Ghosh, S. (2021). Relationship between diameter and depth of potholes controlled by lithology and structure in the Rarh region of India. Current Science, 121 (5), 697–703.

[5]

Bera, B., Bhattacharjee, S., Ghosh, A., Ghosh, S., & Chamling, M. (2019). Dynamic of channel potholes on Precambrian geological sites of Chhota Nagpur plateau, Indian peninsula: Applying fluvio-hydrological and geospatial techniques. SN Applied Sciences, 1, 494.

[6]

Bera, B., & Ghosh, A. (2019). Fluoride dynamics in hydrogeological diversity and Fluoride Contamination Index mapping: A correlation study of North Singbhum Craton, India. Arabian Journal of Geosciences, 12, 802.

[7]

Blumberg, P. N., & Curl, R. L. (1974). Experimental and theoretical studies of dissolution roughness. Journal of Fluid Mechanics, 65 (4), 735–751.

[8]

Černá B., & Engel, Z. (2011). Surface and sub-surface Schmidt hammer rebound value variation for a granite outcrop. Earth SurfaceProcesses and Landforms, 36, 170–179.

[9]

Chakraborty, A., Ghosh, A. K., & Mazumder, A. (2017). Facies analysis of Pleistocene limestones from Neil West Coast Formation, Neil Island, Ritchie’s archipelago of South Andaman, India. Journal of the Geological Society of India, 90 (4), 428–436.

[10]

De Charpentier, J. (1841). Essai sur les glaciers et sur le terrain erratique du bassin du Rhône. M. Ducloux.
[11]

Dhali, M. K., & Biswas, M. (2017). Geo-hydrological response to pothole formation: A quantitative study of Kharsoti River, India. Modeling Earth Systems and Environment, 3, 32.

[12]

Dubinski, I. M., & Wohl, E. (2013). Relationships between block quarrying, bed shear stress, and stream power: A physical model of block quarrying of a jointed bedrock channel. Geomorphology, 180–181, 66–81.

[13]

Dunn, J. A. (1942). Geology and petrology of Eastern Singhbhum and surrounding areas. Memoirs of the Geological Survey of India, 69, 261–456.
[14]

Elston, E. D. (1917). Potholes: Their variety, origin and significance. The Scientific Monthly, 5 (6), 554–567. https://www.jstor.org/stable/22502
[15]

Ghosh, A., & Bera, B. (2023). Landform classification and geomorphological mapping of the Chota Nagpur Plateau, India. Quaternary Science Advances, 10, 100082.

[16]

Gilbert, G. K. (1877). Report on the geology of the Henry Mountains: Geographical and geological survey of the Rocky Mountain region, Gov. Print. Off., Washington, D. C., 1877106.
[17]

Gilbert, G. K. (1906). Moulin work under glaciers, Geological Society of America Bulletin, 17, 317–320.
[18]

Gopal, B. (2016). Unique geological and geomorphic features of River Ken with a bedrock channel. Current Science, 111 (12), 1914–1916. https://www.jstor.org/stable/24911572
[19]

Hancock, G. S., Anderson, R. S., Whipple, K. X., Tinkler, K. J., & Wohl, E. E. (1998). Beyond power: Bedrock River incision process and form. Geophysical Monograph Geophysical Union, 107, 35–60.
[20]

Ji, S., Li, L., & Zeng, W. (2018). The relationship between diameter and depth of potholes eroded by running water. Journal of Rock Mechanics and Geotechnical Engineering, 10 (5), 818–831.

[21]

Ji, S., Zeng, W., Li, L., Ma, Q., & Feng, J. (2019). Geometrical characterization of stream potholes in sandstone from the Sunxi River (Chongqing, China) and implications for the development of bedrock channels. Journal of Asian Earth Sciences, 173, 374–385.

[22]

Johnson, J. P., & Whipple, K. X. (2007). Feedbacks between erosion and sediment transport in experimental bedrock channels. Earth Surface Processes and Landforms: The Journal of the British Geomorphological Research Group, 32 (7), 1048–1062.

[23]

Kale, V. S., & Joshi, V. U. (2004). Evidence of formation of potholes in bedrock on human timescale: Indrayani River, Pune district, Maharashtra. Current Science, 86, 723–726. http://www.jstor.org/stable/24108911
[24]

Kale, V. S., & Shingade, B. S. (1987). A morphological study of potholes of Indrayani knick point (Maharashtra), Explorations in Tropics (pp. 206–214).
[25]

Khedker, V. R. (1950). Mineral resources of the Damodar valley and adjacent region and their utilisation for industrial development. information. www.books.google.com
[26]

Lima, A. G., & Binda, A. L. (2015). Differential control in the formation of river potholes on basalts of the Paraná Volcanic Province. Journal of South American Earth Sciences, 59, 86–94.

[27]

Ljunger, E. (1930). Spaltentektonik und morphologie der schwedichenSkagerak-Küste. Bulletin of the Geological Institution of Uppsala 21, 255–475.
[28]

Lorenc, M. W., & Alonso, J. S. (1980). Remarks on the pothole erosion at the Tormes River (Salamanca Province, Spain). Acta geológicahispánica, 3, 91–93.
[29]

Lorenc, M. W., Barco, P., & Saavedra, J. (1994). The evolution of potholes in granite bedrock, W Spain. Catena, 22 (4), 265–274.

[30]

Mageswaran, T., Sachithanandam, V., Sridhar, R., Thirunavukarasu, E., & Ramesh, R. (2015). Mapping and monitoring of land use/land cover changes in Neil Island (South Andaman) using geospatial approaches. IJMS, 44 (11), 1762–1768. http://nopr.niscpr.res.in/handle/123456789/35018
[31]

Miller, J. R. (1991). The influence of bedrock geology on knickpoint development and channel-bed degradation along downcutting streams in south-central Indiana. The Journal of Geology, 99 (4), 591–605.

[32]

Morelli, M., & Piana, F. (2006). Comparison between remote sensed lineaments and geological structures in intensively cultivated hills (Monferrato and Langhe domains, NW Italy). International Journal of Remote Sensing, 27, 4471–4493.

[33]

Niedzielski, T., Migoń P., & Placek, A. (2009). A minimum sample size required from Schmidt hammer measurements. Earth Surface Processes and Landforms, 34 (13), 1713–1725.

[34]

Ortega, J. A., Gómez-Heras, M., Perez-López, R., & Wohl, E. (2014). Multiscale structural and lithologic controls in the development of stream potholes on granite bedrock rivers. Geomorphology, 204, 588–598.

[35]

Pandey, O. P. (2020). Geodynamic evolution of the Indian shield: Geophysical aspects. Springer. https://link.springer.com/book/10.1007/978-3-030-40597-7
[36]

Pelletier, J. D., Sweeney, K. E., Roering, J. J., & Finnegan, N. J. (2015). Controls on the geometry of potholes in bedrock channels. Geophysical Research Letters, 42 (3), 797–803.

[37]

Rasool, Q. A., Singh, V. K., & Singh, U. C. (2011). The evaluation of Morphmetric characteristics of Upper Subarnarekha Watershed drainage basin using geoinformatics as a tool, Ranchi, Jharkhand. International Journal of Environmental Sciences, 1 (7), 1924–1930. https://www.indianjournals.com/ijor.aspx?target=ijor:ijes&volume=1&issue=7&article=047
[38]

Rudra, K., & Rudra, K. (2018). Rivers of the Tarai–Doors and Barind Tract, Rivers of the Ganga-Brahmaputra-Meghna delta: A fluvial account of Bengal (pp. 27–47).

[39]

Schowengerdt, R. A. (2006). Remote sensing: Models and methods for image processing. Elsevier.
[40]

Selby, M. J. (1980). A rock mass strength classification for geomorphic purposes: With tests from Antarctica and New Zealand. Zeitschrift für Geomorphologie, 24, 31–51.

[41]

Sengupta, S., & Kale, V. S. (2011). Evaluation of the role of rock properties in the development of potholes: A case study of the Indrayani knickpoint, Maharashtra. Journal of Earth System Science, 120, 157–165.

[42]

Shepherd, R. G., & Schumm, S. A. (1974). Experimental study of river incision. Geological Society of America Bulletin, 85 (2), 257–268.

[43]

Singh, A. K., & Giri, S. (2018). Subarnarekha River: The gold streak of India, The Indian rivers: Scientific and socio-economic aspects (pp. 273–285). Springer.

[44]

Singh, O. P. (1982). Tertiary uplifts, Perspectives in geomorphology: Essays on Indian geomorphology (p. 211).
[45]

Singh, R. P. (1969). Geomorphological evolution of Chotanagpur Highlands-India (pp. 64–72). National Geographical Society of India.
[46]

Singh, S. (2014). Geomorphology. Pravalika Publications.
[47]

Sklar, L. S., & Dietrich, W. E. (2001). Sediment and rock strength controls on river incision into bedrock. Geology, 29 (12), 1087–1090.

[48]

Sklar, L. S., & Dietrich, W. E. (2004). A mechanistic model for river incision into bedrock by saltating bed load. Water Resources Research, 40 (6), 1–22.

[49]

Springer, G. S., Tooth, S., & Wohl, E. E. (2005). Dynamics of pothole growth as defined by field data and geometrical description. Journal of Geophysical Research: Earth Surface, 110(F4), 1–10.

[50]

Springer, G. S., Tooth, S., & Wohl, E. E. (2006). Theoretical modeling of stream potholes based upon empirical observations from the Orange River, Republic of South Africa. Geomorphology, 82(1–2), 160–176.

[51]

Springer, G. S., & Wohl, E. E. (2002). Empirical and theoretical investigations of sculpted forms in Buckeye Creek Cave, West Virginia. The Journal of Geology, 110 (4), 469–481.

[52]

Viles, H., Goudie, A., Grab, S., & Lalley, J. (2011). The use of the Schmidt hammer and Equotip for rock hardness assessment in geomorphology and heritage science: A comparative analysis. Earth Surface Processes and Landforms, 36 (3), 320–333.

[53]

Villalta Echeverria, M. D. P., Viña Ortega, A. G., Larreta, E., Romero Crespo, P., & Mulas, M. (2022). Lineament extraction from digital terrain derivate model: A case study in the Girón–Santa Isabel basin, South Ecuador. Remote Sensing, 14 (21), 5400.
[54]

Wang, W., Liang, M., & Huang, S. (2009). Formation and development of stream potholes in a gorge in Guangdong. Journal of Geographical Sciences, 19, 118–128.

[55]

Wang, W., Xu, L., Wu, Z., & Huang, S. (2010). Shape and spatial distribution features of marine potholes on the coast of Shenzhen, China. Acta Geographica Sinica, 65 (3), 320–330.
[56]

Whipple, K. X., Hancock, G. S., & Anderson, R. S. (2000). River incision into bedrock: Mechanics and relative efficacy of plucking, abrasion, and cavitation. Geological Society of America Bulletin, 112, 490–503.

[57]

Wohl, E., & Merritt, D. M. (2008). Reach-scale channel geometry of mountain streams. Geomorphology, 93(3–4), 168–185.

[58]

Wohl, E. E. (1993). Bedrock channel incision along Piccaninny Creek, Australia. The Journal of Geology, 101 (6), 749–761.

[59]

Wohl, E. E., Greenbaum, N., Schick, A. P., & Baker, V. R. (1994). Controls on bedrock channel incision along Nahal Paran, Israel. Earth Surface Processes and Landforms, 19 (1), 1–13.

[60]

Yin, D., Peakall, J., Parsons, D., Chen, Z., Averill, H. M., Wignall, P. & Best, J. (2016). Bedform genesis in bedrock substrates: Insights into formative processes from a new experimental approach and the importance of suspension-dominated abrasion. Geomorphology, 255, 26–38.

RIGHTS & PERMISSIONS

2025 The Author(s). River published by Wiley-VCH GmbH on behalf of China Institute of Water Resources and Hydropower Research (IWHR).

AI Summary AI Mindmap
PDF (8119KB)

270

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/