Terrain

Terrain or relief (also topographical relief) involves the vertical and horizontal dimensions of land surface. The term bathymetry is used to describe underwater relief, while hypsometry studies terrain relative to sea level. The Latin word terra (the root of terrain) means "earth."

Relief map of Sierra Nevada, Spain
A shaded and colored image (i.e. terrain is enhanced) of varied terrain from the Shuttle Radar Topography Mission. This shows elevation model of New Zealand's Alpine Fault running about 500 km (300 mi) long. The escarpment is flanked by a vast chain of hills between the fault and the mountains of New Zealand's Southern Alps. Northeast is towards the top.

In physical geography, terrain is the lay of the land. This is usually expressed in terms of the elevation, slope, and orientation of terrain features. Terrain affects surface water flow and distribution. Over a large area, it can affect weather and climate patterns.

Importance

The understanding of terrain is critical for many reasons:

Relief

Relief (or local relief) refers specifically to the quantitative measurement of vertical elevation change in a landscape. It is the difference between maximum and minimum elevations within a given area, usually of limited extent.[3] The relief of a landscape can change with the size of the area over which it is measured, making the definition of the scale over which it is measured very important. Because it is related to the slope of surfaces within the area of interest and to the gradient of any streams present, the relief of a landscape is a useful metric in the study of the Earth's surface. Relief energy, which may be defined inter alia as "the maximum height range in a regular grid",[4] is essentially an indication of the ruggedness or relative height of the terrain.

Geomorphology

Geomorphology is in large part the study of the formation of terrain or topography. Terrain is formed by concurrent processes operating on the underlying geological structures over geological time:

Tectonic processes such as orogenies and uplifts cause land to be elevated, whereas erosional and weathering processes wear the land away by smoothing and reducing topographic features.[5] The relationship of erosion and tectonics rarely (if ever) reaches equilibrium.[6][7][8] These processes are also codependent, however the full range of their interactions is still a topic of debate.[9][10][11][12][13]

Land surface parameters are quantitative measures of various morphometric properties of a surface. The most common examples are used to derive slope or aspect of a terrain or curvatures at each location. These measures can also be used to derive hydrological parameters that reflect flow/erosion processes. Climatic parameters are based on the modelling of solar radiation or air flow.

Land surface objects, or landforms, are definite physical objects (lines, points, areas) that differ from the surrounding objects. The most typical examples airlines of watersheds, stream patterns, ridges, break-lines, pools or borders of specific landforms.

See also

References

  1. Baker, N.T., and Capel, P.D., 2011, "Environmental factors that influence the location of crop agriculture in the conterminous United States": U.S. Geological Survey Scientific Investigations Report 2011–5108, 72 p.
  2. Brush, L. M. (1961). "Drainage basins, channels, and flow characteristics of selected streams in central Pennsylvania" (pp. 1-44) (United States, U.S. Department of the Interior, GEOLOGICAL SURVEY). Washington D.C.: UNITED STATES GOVERNMENT PRINTING OFFICE. Retrieved October 29, 2017, from https://pubs.usgs.gov/pp/0282f/report.pdf
  3. Summerfield, M.A., 1991, Global Geomorphology, Pearson, 537 p. ISBN 9780582301566
  4. African Landscapes: Interdisciplinary Approaches, edited by Michael Bollig, Olaf Bubenzer. Cologne: Springer, 2009, p. 48.
  5. Strak, V., Dominguez, S., Petit, C., Meyer, B., & Loget, N. (2011). Interaction between normal fault slip and erosion on relief evolution; insights from experimental modelling. Tectonophysics, 513(1-4), 1-19. doi:10.1016/j.tecto.2011.10.005
  6. Gasparini, N., Bras, R., & Whipple, K. (2006). Numerical modeling of non–steady-state river profile evolution using a sediment-flux-dependent incision model. Special Paper - Geological Society of America, 398, 127-141. doi:10.1130/2006.2398(08)
  7. Roe, G., Stolar, D., & Willett, S. (2006). Response of a steady-state critical wedge orogen to changes in climate and tectonic forcing. Special Paper - Geological Society of America, 398, 227-239. doi:10.1130/2005.2398(13)
  8. Stolar, D., Willett, S., & Roe, G. (2006). Climatic and tectonic forcing of a critical orogen. Special Paper - Geological Society of America, 398, 241-250. doi:10.1130/2006.2398(14)
  9. Wobus, C., Whipple, K., Kirby, E., Snyder, N., Johnson, J., Spyropolou, K., Sheehan, D. (2006). Tectonics from topography: Procedures, promise, and pitfalls. Special Paper - Geological Society of America, 398, 55-74. doi:10.1130/2006.2398(04)
  10. Hoth, S., Adam, J., Kukowski, N., & Oncken, O. (2006). Influence of erosion on the kinematics of bivergent orogens: Results from scaled sandbox simulations. Special Paper - Geological Society of America, 398, 201-225. doi:10.1130/2006.2398(12)
  11. Bonnet, C., J. Malavieille, and J. Mosar (2007), Interactions between tectonics, erosion, and sedimentation during the recent evolution of the Alpine orogen: Analogue modeling insights, Tectonics, 26, TC6016, doi:10.1029/2006TC002048
  12. University of Cologne. "New insights into the relationship between erosion and tectonics in the Himalayas." ScienceDaily. ScienceDaily, 23 August 2016. <www.sciencedaily.com/releases/2016/08/160823083555.htm>
  13. King, G., Herman, F., & Guralnik, B. (2016). Northward migration of the eastern himalayan syntaxis revealed by OSL thermochronometry. Science, 353(6301), 800-804. doi:10.1126/science.aaf2637

Further reading

The dictionary definition of terrain at Wiktionary

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