loading page

Application of Grain-Size End-Member Modelling in Bed Sediments of the Brahmaputra River
  • +2
  • Abhishek Dixit,
  • sourav kumar,
  • Chandan Mahanta,
  • Sumantra Chaudhari,
  • Manish singh Rana
Abhishek Dixit
IIT Guwahati

Corresponding Author:abhishek.dixit@iitg.ac.in

Author Profile
sourav kumar
IIT Guwahati
Author Profile
Chandan Mahanta
IIT Guwahati
Author Profile
Sumantra Chaudhari
IIT Guwahati
Author Profile
Manish singh Rana
IIT Guwahati
Author Profile

Abstract

Superimposed signatures of grain size effect, lithology and chemical processes on fluvial sediments need to be resolved to answer the profound research questions related to sediment provenance and processes. Hydraulic forces sort the sediments into different grain size classes in the river water column. The finest fraction is transported as the suspended sediments which have different sediment composition than the bed sediments. Thus, suspended sediment may provide additional information about earth surface processes, such as chemical weathering. Hydraulically sorted river bed sediments may or may not provide this information, as bulk sample may be depleted in finer grains by hydraulic processes. Bed sediments that are easily sampled from the sand bars and river banks are often investigated to study the weathering intensity and sediment provenance. It is thus crucial to identify and quantify the specific grain size classes in the bulk sample to be investigated for the research question at hand. End Member Modelling Algorithms (EMMA) for grain size distribution is a useful tool to unmix the grain size population into geological meaningful end members. We applied Hierarchical alternating least squares nonnegative matrix factorization (HALS-NMF) algorithm to unmix the grain size data (62 samples) of river bed sediments collected from the freshly exposed sand bars of the Brahmaputra river over a stretch of 550km. The grain size distribution of the finest end member (mean=18µm) is closely approximated to be of the surface sediment grain size distribution reported previously for the Brahmaputra river. Thus, we were able to quantify the relative contribution of suspended sediment to the bed sediment of the Brahmaputra trunk. Results show that the contribution of the suspended sediments in the bed sediment is higher at the lower reaches of the river near floodplain outlet, possibly due to the reduced flow energy in downstream regions. The findings may also be used to select samples and grain size classes for additional geochemical and mineralogical study in order to interpret signals of weathering, provenance and physical processes in the Brahmaputra’s large dynamic floodplains at a finer spatial scale.