Downstream rounding rate of pebbles in the Himalaya

Pokhrel, Prakash; Attal, Mikael; Sinclair, Hugh D.; Mudd, Simon M.; Naylor, Mark

doi:10.5194/esurf-12-515-2024

Earth Surf. Dynam.

2024

DOI: 10.5194/esurf-12-515-2024

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Downstream rounding rate of pebbles in the Himalaya

Prakash Pokhrel,

Mikael Attal,

Hugh D. Sinclair

et al.

Abstract: Abstract. Sediment grains are progressively rounded during their transport down a river. For more than a century, Earth scientists have used the roundness of pebbles within modern sediment, and of clasts within conglomerates, as a key metric to constrain the sediment's transport history and source area(s). However, the current practices of assessment of pebble roundness are mainly qualitative and based on time-consuming manual measurement methods. This qualitative judgement provides the transport history only … Show more

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Cited by 3 publications

References 66 publications

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Influence of particle lithology, size and angularity on rates and products of bedload wear: An experimental study

Bray,

Litwin‐Miller,

Cardona

et al. 2024

Earth Surf Processes Landf

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Physical wear during bedload transport influences downstream changes in the size distributions and shapes of riverbed sediment, which in turn affect myriad fluvial processes ranging from incision into bedrock to provision of aquatic habitat. Here we use laboratory tumbling experiments to address several remaining knowledge gaps, including the roles of lithologic susceptibility to fragmentation, particle size distributions and particle angularity in controlling wear rates and the size distribution of wear products. To focus on the dynamics of particle wear in headwater channels, we used initially angular sediment and ran the experiments until 10% of the initial bedload particle mass had been lost to fine‐grained wear products. We measured individual particle mass and diameter by hand and used photo analysis to quantify particle shape and angularity. We find strikingly different wear patterns between limestone and welded tuff. Although wear rates in the tuff were an order of magnitude slower than the limestone, tuff wear was primarily by fragmentation while limestone wear was dominantly by attrition. Fragmentation of the tuff resulted in a widening of the bedload size distribution, a lack of consistent particle rounding and a fine‐wear product dominated by sand. In contrast, limestone particles rounded substantially and produced silt‐sized wear products. Differences in wear product size and susceptibility to fragmentation may reflect contrasts in the size distribution of mineral crystals in each lithology. Wear rates in both rock types declined substantially with increasing cumulative mass loss, due to rounding in the limestone and reduced fragmentation in the tuff. These results suggest that applications of the conventional exponential model to predict mass loss with travel distance need to account for lithologic influence on susceptibility to fragmentation and the influence of rounding on particle wear rates.

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Influence of particle lithology, size and angularity on rates and products of bedload wear: An experimental study

Bray,

Litwin‐Miller,

Cardona

et al. 2024

Earth Surf Processes Landf

View full text Add to dashboard Cite

show abstract

Grain size and shape analysis of recent and paleo sediments along Poyang Lake with insight into its environmental significance

Hu,

Xiao,

Fan

et al. 2025

CATENA

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Downstream rounding rate of pebbles in the Himalaya

Pokhrel,

Attal,

Sinclair

et al. 2024

Earth Surf. Dynam.

View full text Add to dashboard Cite

Abstract. Sediment grains are progressively rounded during their transport down a river. For more than a century, Earth scientists have used the roundness of pebbles within modern sediment, and of clasts within conglomerates, as a key metric to constrain the sediment's transport history and source area(s). However, the current practices of assessment of pebble roundness are mainly qualitative and based on time-consuming manual measurement methods. This qualitative judgement provides the transport history only in a broad sense, such as classifying distance as “near” or “far”. In this study, we propose a new model that quantifies the relationship between roundness and the transport distance. We demonstrate that this model can be applied to the clasts of multiple lithologies including modern sediment, as well as conglomerates, deposited by ancient river systems. We present field data from two Himalayan catchments in Nepal. We use the normalized isoperimetric ratio (IRn), which relates a pebble's area (A) to its perimeter (P), to quantify roundness. The maximum analytical value for IRn is 1, and IRn is expected to increase with transport distance. We propose a non-linear roundness model based on our field data, whereby the difference between a grain's IRn and the maximum value of 1 decays exponentially with transport distance, mirroring Sternberg's model of mass loss or size reduction by abrasion. This roundness model predicts an asymptotic behaviour for IRn, and the distance over which IRn approaches the asymptote is controlled by a rounding coefficient. Our field data suggest that the roundness coefficient for granite pebbles is 9 times that of quartzite pebbles. Using this model, we reconstruct the transport history of a Pliocene paleo-river deposit preserved at the base of the Kathmandu intermontane basin. These results, along with other sedimentary evidence, imply that the paleo-river was much longer than the length of the Kathmandu Basin and that it must have lost its headwaters through drainage capture. We further explore the extreme rounding of clasts from Miocene conglomerate of the Siwalik zone and find evidence of sediment recycling.

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Downstream rounding rate of pebbles in the Himalaya

Cited by 3 publications

References 66 publications

Influence of particle lithology, size and angularity on rates and products of bedload wear: An experimental study

Influence of particle lithology, size and angularity on rates and products of bedload wear: An experimental study

Grain size and shape analysis of recent and paleo sediments along Poyang Lake with insight into its environmental significance

Downstream rounding rate of pebbles in the Himalaya

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