Glacial motion is the motion of glaciers, which can be likened to rivers of ice. It has played an important role in sculpting many landscapes. Most lakes in the world occupy basins scoured out by glaciers. Glacial motion can be fast (up to , observed on Jakobshavn Isbræ in Greenland) or slow ( on small glaciers or in the center of ice sheets), but is typically around .
Glacier motion occurs from four processes, all driven by gravity: basal sliding, glacial quakes generating fractional movements of large sections of ice, bed deformation, and internal deformation.
As discussed in the previous section, glaciers move and flow downslope due to (a) deformation or (b) sliding. The flow of material through a glacier is generally not constant at various points within the glacier itself, but is rather faster or slower depending on a plethora of contributing factors. One way to describe these factors is by describing their impact on glacier stresses. One may distinguish between two kinds of stresses: driving stresses (for which gravity causes the glacier to flow downslope) or resistive stresses (which prevent the glacier's downslope acceleration).
Stress is a vector quantity with units of force per unit area. It is a useful quantity for describing glacial movement because the efficacy of a force (such as gravity or friction) is emphasized or weakened depending on the area over which it is distributed. For the purposes of describing glacial motion, we can classify all stresses as either (a) normal stresses which act perpendicular to a surface of interest or (b) shear stresses which act transversely to a surface of interest.
Glacial ice experiences a driving stress due to basal shear stresses, which are shear stresses on the glacial bed. For a basic model of basal shear stress, we may say that:
Where alpha is the slope of the glacial bed, rho is the ice density, g is the acceleration of gravity, and h is the ice thickness. Also note that:
Where sigma is the normal stress experienced by the glacial bed due to the weight of the glacial ice. As such, the shear stress is simply the downslope component of the glacial ice's weight. It is thus evident that the stress state of the glacier is not constant through the thickness of the glacier, because the normal stress increases closer to the glacial bed due to higher weight being carried on lower layers (indeed the stress varies ~linearly with depth). Regardless, under this driving shear stress, the glacial ice will deform, experiencing non-linear viscous flow. The relationship for the amount of deformation and driving shear stress can be modeled using the Glen-Nye Flow Law which states that:
In essence the rate of strain (deformation per unit length of the glacier) is proportional to a constant A times the basal shear stress to the power of n, another constant.
In addition to the deformation of the glacier, there is also basal sliding, which is movement/sliding of the glacier relative to the rock bed that it sits on. Glacier flow velocity is the sum of deformation and basal sliding.
If a glacier's terminus moves forward faster than it melts, the net result is advance. Glacier retreat occurs when more material ablates from the terminus than is replenished by flow into that region.
Glaciologists consider that trends in mass balance for glaciers are more fundamental than the advance or retreat of the termini of individual glaciers. In the years since 1960, there has been a striking decline in the overall volume of glaciers worldwide. This decline is correlated with global warming. As a glacier thins, due to the loss of mass it will slow down and crevassing will decrease.
Studying glacial motion and the landforms that result requires tools from many different disciplines: physical geography, climatology, and geology are among the areas sometime grouped together and called earth science.
During the Pleistocene (the last ice age), huge sheets of ice called continental glaciers advanced over much of the earth. The movement of these continental glaciers created many now-familiar glacial landforms. As the glaciers were expanded, due to their accumulating weight of snow and ice, they crushed and redistributed surface rocks, creating erosional landforms such as s, cirques, and hanging valleys. Later, when the glaciers retreated leaving behind their freight of crushed rock and sand, depositional landforms were created, such as moraines, eskers, drumlins, and kames. The stone walls found in New England (northeastern United States) contain many glacial erratics, rocks that were dragged by a glacier many miles from their bedrock origin.
At some point, if an Alpine glacier becomes too thin it will stop moving. This will result in the end of any basal erosion. The stream issuing from the glacier will then become clearer as glacial flour diminishes. Lakes and ponds can also be caused by glacial movement. Kettle lakes form when a retreating glacier leaves behind an underground chunk of ice. Moraine-dammed lakes occur when a stream (or snow runoff) is dammed by glacial till.