Grain-size and morphoscopy analyses of surficial cover associated with an alluvial fan complex and low river terraces in the Grande and Fêmeas Rivers, western region of the state of Bahia, Brazil.
- 1Federal University of Western Bahia, Geology, Brazil (taniaaugusto@ufob.edu.br)
- 2Federal University of Western Bahia, Geology, Brazil (icaro.m4471@ufob.edu.br)
- 3Federal University of Western Bahia, Geology, Brazil (joao.b7728@ufob.edu.br)
- 4Federal University of Western Bahia, Geology, Brazil (artur.b7623@ufob.edu.br)
- 5Federal University of Western Bahia, Geology, Brazil (emanuelly2401@gmail.com)
- 6Federal University of Viçosa, Department of Soils, Brazil (jjlelis@gmail.com)
- 7Federal University of Western Bahia, Geology, Brazil (andreos@ufob.edu.br)
Located in the western region of Bahia state, Brazil, the Fêmeas and Grande rivers are important tributaries of the São Francisco River. Despite the significance of these systems for the regional and national contexts, few studies have addressed the geomorphological processes and dynamics throughout the Holocene in these areas. Thus, through the characterization of grain size and morphoscopy of 100 quartz grains from deposits corresponding to an alluvial fan complex and low fluvial terrace on the left bank of the Fêmeas River, as well as two low fluvial terraces of the Grande River (one on each bank), we aim to identify discontinuities indicative of changes in morphodynamic processes throughout the Holocene. The results have shown that in the low fluvial terrace on the left bank of the Grande River, the deeper layers (45-90 cm) present values for the silt and clay fractions of 1.7% and 1.3%, respectively. On the other hand, in the more superficial layer (0-10 cm), the values for the silt and clay fractions were 5.5% and 6.7%, respectively. The values for the fine sand fraction in all layers averaged from 69.8% to 86.4%. No changes were observed in the morphoscopy of quartz grains, with rounded and sub-discoidal grains being predominant. On the right bank, the fluvial deposit predominantly showed silt and clay fractions with values of 24.8% and 29.9% at greater depths (40-60 cm), while on the surface (0-30 cm), the values for these fractions significantly decreased, reaching values of 6.3% and 12.7%. Morphoscopy analyses resulted in mostly sub-rounded and sub-discoidal grains. In the alluvial fan complex of the Fêmeas River basin, erosive-depositional discontinuities were identified in a deposit corresponding to the proximal facies of the complex. The results have shown differentiations in the clay, silt, fine sand, and coarse sand fractions at 0-70 cm, as well as an increase in the clay fraction in deeper layers, with values ranging between 36.9% and 40.8%. Morphoscopy analyses indicated 36.8% sub-rounded grains and 50% spherical-rounded grains. In another deposit with a thickness of 140 cm and corresponding to the distal facies of the alluvial fan complex, the results showed a decrease in coarse sand values to fine sand in deeper layers. Morphoscopy indicated predominantly sub-rounded grains in the more superficial layers (0-50 cm), predominantly rounded grains in the intermediate layer (50-70 cm), while the deeper layers (70-140 cm) presented sub-rounded and rounded grains. Overall, this deposit showed 13.2% sub-angular grains. Finally, our results indicated significant variations in silt and clay fractions, which, when analysed together with morphoscopy, suggest energetic variations in depositional processes throughout the Holocene. This research has been funded by the Bahia State Research Support Foundation (Grant 4341/2022).
How to cite: Santos, T. A. D. S., Machado, I. G. L., Bedendo, J. P., Brito, A. M., Silva, E. C. L., de Souza, J. J. L. L., and Souza, A. D. O.: Grain-size and morphoscopy analyses of surficial cover associated with an alluvial fan complex and low river terraces in the Grande and Fêmeas Rivers, western region of the state of Bahia, Brazil., EGU General Assembly 2024, Vienna, Austria, 14–19 Apr 2024, EGU24-10220, https://doi.org/10.5194/egusphere-egu24-10220, 2024.