Channel characteristics and planform dynamics of the lower Niger River, Niger Delta Basin (1985–2015)

Authors

  • Tombra Akana Pan African University and Niger Delta University
  • Olubunmi Adeigbe university of ibadan

DOI:

https://doi.org/10.7494/geol.2019.45.4.291

Keywords:

delta, channel dynamics, avulsion, human activities, GIS, Niger River Valley

Abstract

This study used repeat satellite imagery and Geographic Information System analysis to assess the planform dynamics along the length of the lower Niger River Valley from Onitsha city to the coast between 1985 and 2015. The aim is to understand the altered dynamics and its plausible causes in this data-poor region. Analyses revealed that the Niger River has undergone change corresponding to enhanced instability in terms of an increased rate of erosion. In the study area, a change was observed from 3.7% of deposition in the first 10 years (1985–1995) to 3.9% of erosion in the next 10 years (1995–2005) and 4.7% of erosion in the last 10 years (2005–2015). Total erosion over the 30-year period (1985–2015) in the delta was calculated on 4.8%. The river channel has migrated toward the east in the upper and lower reaches while the mid-section of the channel is migrating towards the west. The east river bank is observed to be more unstable compared to west bank line through the study period. The maximum shifts identified were 3.35 km of deposition in 10 years (1985–1995), 3.31 km of erosion in the next 10 years (1995–2005), and another substantial erosional shift of 3.35 km in the next 10 years (2005–2015). Avulsion rates gradually moved from −42.1 m∙year−1 (1985–2005, segment F) to 100.2 m∙year−1 (1985–1995, segment D), large deposition in the first 10 years. Total avulsion rates of the delta in the last 30 years (1985–2015) has pointed on erosion (−2.2 m∙year−1). The altered dynamics observed would likely threaten the future of the fragile lower river system environment and raise concerns for operators with infrastructure within the Niger Delta.

Downloads

Download data is not yet available.

Author Biographies

Tombra Akana, Pan African University and Niger Delta University

Department of Geology

Olubunmi Adeigbe, university of ibadan

Department of Geology

References

Abaje I.B, Ati O.F. & Iguisi E.O., 2015. Recent Trends and Fluctuations of Annual Rainfall in the Sudano-Sahelian Ecological Zone of Nigeria: Risks and Opportunities. Journal of Sustainable Society, 1, 2, 44–51.

Adejuwon J.O., 2012. Rainfall seasonality in the Niger Delta Belt. Nigeria. Journal of Geography and Regional Planning, 5 (2), 51–60.

Azuwike D.O. & Enwereuzor A.I., 2011. Effect of Rainfall Variability on Water Supply in Ikeduru L.G.A. of Imo State, Nigeria. African Research Review. International Multidisciplinary Journal, Ethiopia, 5 (5), 22, 223–241.

Batalla R.J., Gomez C.M. & Kondolf G.M., 2004. Reservoir-induced hydrological changes in the Ebro River basin (NE Spain). Journal of Hydrology, 290, 117–136.

Beechie T., Liermann M., Pollock M., Baker S. & Davies J., 2006. Channel Pattern and River Floodplain Dynamics in Forested Mountain River Systems. Geomorphology, 78, 124–141. DOI: https://doi.org/10.1016/j.geomorph.2006.01.030.

Bridge J.S., 2003. Rivers and Flood Plains: Forms, Processes, And Sedimentary Record. Blackwell, New York.

Dhari S.D., Arya S. & Murumkar A.R., 2015. Application of remote sensing and GIS in sinuosity and river shifting analysis of the Ganges River in Uttarakhand plains. Applied Geomatics, 7, 13–21.

FAO, 1997. Irrigation potential in Africa: A basin approach, The Niger Basin. Food and Agricultural Organization, archived 2017.07.21 at the Wayback Machine.

Goswami U., Sarma J.N. & Patgiri A.D., 1999. River channel changes of the Subansiri in Assam, India. Geomorphology, 30, 227–244.

Gurnell A.M., 1997. Channel change on the River Dee meanders, 1946–1992, from the analysis of air photographs. Regulated Rivers: Research & Management, 13, 1, 13–26.

Kesel R.H., 2003. Human modifications to the sediment regime of the Lower Mississippi River flood plain. Geomorphology, 56, 325–334.

Leopold L.B., Wolman G.M. & Miller J.P., 1964. Fluvial Processes in Geomorphology. Dover Publications, New York.

Lillesand T.M. & Kiefer R.W., 2000. Remote Sensing and Image Interpretation. 4th ed. John Wiley & Sons, New York.

Masselink R., Temme A.J.A.M., Giménez R., Casalí J. & Keesstra S., 2017. Assessing hillslope-channel connectivity in an agricultural catchment using rare-earth oxide tracers and random forests models. Cuadernos de Investigación Geográfica – Geographical Research Letters, 43 (1), 19–39. DOI: http://dx.doi.org/10.18172/cig.3169.

McKnight T.L. & Hess D., 2005. The Fluvial Processes. Physical Geography: A Landscape Appreciation. 8th ed. Pearson, Prentice Hall, Upper Saddle River, New Jersey.

Mitra D., Anjani K., Tangri A.K. & Singh I.B., 2005. Channel avulsions of the Sarda River system, Ganga Plain. International Journal Remote Sensing, 26 (5), 929–936.

Mount J.F., 1995. California Rivers and Stream: Conflict between fluvial Process and Land Use. University of California Press, Berkeley.

Murgatroyd A.L. & Ternan J.L., 1983. The impact of afforestation on stream bank erosion and channel form. Earth Surface Processes and Landforms, 8, 357–369.

Odjugo P.A.O., 2006. An analysis of rainfall patterns in Nigeria. Global Journal of Environmental Sciences, 4 (2), 139–145.

Prasad N., 1982. Some aspects of meandering streams of the Barakar basin and their sinuosity indexes. [in:] Sharma HS (ed.), Perspectives in Geomorphology: Essays on Indian Geomorphology, 4, Concept Publishers, New Delhi, 93–101.

Reader J., 2001. Africa. National Geographic Society, Washington, D.C.

Schumm S.A., 1963. Sinuosity of alluvial rivers of Great Plains. Bulletin of the Geological Society of America, 74, 1089–1099.

Snow R.S., 1989. Fractal sinuosity of streams. Pure and Applied Geophysics, 131 (1–2), 99–109.

Surian N., 1999. Channel changes due to river regulation: the case of the Piave River, Italy. Earth Surface Processes and Landforms, 24, 1135–1151.

Surian N. & Rinaldi M., 2003. Morphological response to river engineering and management in alluvial channels in Italy. Geomorphology, 50, 307–326.

Tiegs S.D. & Pohl M., 2005. Planform channel dynamics of the lower Colorado River: 1976–2000. Geomorphology, 69 (1), 14–27.

Vanacker V., Molina A., Govers G., Poesen J., Dercon G. & Deckers S., 2005. River channel response to short-term human-induced change in landscape connectivity in Andean ecosystems. Geomorphology, 72, 340–353.

Ward P.D., Montgomery D.R. & Smith R., 2000. Altered river morphology in South Africa related to Permian-Triassic extinction. Science, 289 (5485), 1740–1743.

Wellmeyer J.L., Slattery M.C. & Phillips J.D., 2005. Quantifying downstream impacts of impoundment on flow regime and channel planform, lower Trinity River, Texas. Geomorphology, 69, 1–13.

Winterbottom S.J., 2000. Medium and short-term channel planform changes on the River Tay and Tummel, Scotland. Geomorphology, 34, 195–208.

Yousefi S., Mirzaee S., Keesstra S., Surian N., Zakizadeh R. & Tabibian S., 2017. Effects of an extreme flood on river morphology (case study: Karoon River, Iran). Geomorphology, 304, 30–39.

Downloads

Published

2020-01-25

How to Cite

Akana, T., & Adeigbe, O. (2020). Channel characteristics and planform dynamics of the lower Niger River, Niger Delta Basin (1985–2015). Geology, Geophysics and Environment, 45(4), 291. https://doi.org/10.7494/geol.2019.45.4.291

Issue

Vol. 45 No. 4 (2019)

Section

Articles

License

Licencja Creative Commons

Authors have full copyright and property rights to their work. Their copyrights to store the work, duplicate it in printing (as well as in the form of a digital CD recording), to make it available in the digital form, on the Internet and putting into circulation multiplied copies of the work worldwide are unlimited.

The content of the journal is freely available according to the Creative Commons License Attribution 4.0 International (CC BY 4.0)