Rates of coastal recession and stability

Geology

Rock type	Examples	Erosion Rate and Explanation
Igneous	Granite, basalt	VERY SLOW (<1mm per yr) • Rocks are crystalline, strong and resistant • Granite has few joints for erosion to exploit
Metamorphic	Slate, schist, marble	SLOW (1-3mm per yr) • Rocks generally resistant • Some may have crystals oriented in one direction, or may be folded and faulted so have areas of weakness
Sedimentary	Sandstone, limestone, shale	MODERATE TO FAST (5-10mm per yr) • Rocks are clastic (stuck together in layers) and less resistant • Rocks with many natural bedding planes (strata) are most vulnerable (shale)
Unconsolidated	Boulder clay, sand	VERY FAST (2-10m per yr) • Very weak materials ∴ easily eroded

Many cliff coastlines are made of layers of different rock types and so erosion rates vary (complex cliff profiles)
- Either because of general resistance to erosion or vulnerability to chemical weathering (chalk)

Allow water to pass through (sandstone & limestone)
Impermeable = no water can pass through (clays, mudstone etc) A cliff with permeable rock strata above an impermeable, weakly consolidated rock strata is vulnerable to mass movement

↳ As rainwater percolating into the upper strata creates instability

High pore water pressure can also impact general stability - The pressure water experiences at a particular point below the water table due to the weight of water above it

Many coastlines are protected from erosion of unconsolidated sediment by the stabilising influence of plants. These include:

Roots bind sediments together so increases ↑ their resistance to erosion
When submerged, plants growing w/in sediment provide surface protection so surface sediment not directly exposed to moving water
Protect sediment from wind erosion by reducing wind speed through friction
As plants lose leaves and die, they add organic material to the sand, which eventually forms soil - Humus

Halophytes → Can tolerate salt water, either around roots, being submerged (at high tide) or salt spray from the sea
Xerophytes → Can tolerate very dry conditions, such as on sand dunes where the sandy soil stores little water due to drainage ↳ Due to the combined salt, strong winds, dry conditions etc, only plants w/ special adaptations are able to survive

Plant succession Refers to the way vegetation on sandy coastlines change over time, from pioneer species, which initially colonise the bare sand or mud, to the climax stage
Plants are specially adapted to conditions (Halophytes & Xerophytes)
Sand dunes (psammosere) and salt marshes (halosere) both have plant successions that help stabilise the soil

↳ Succession → The changing structure of a plant community over time as an area of initially bare sediment is colonised by plants

On a coastline, certain very specialised plants will begin to grow in the bare sand or mud (pioneer species)
New plants can then tolerate the conditions made by the embryo dunes creating foredunes
The process continues going from yellow dunes (marram grass), to grey dunes (gorse) along with dune slacks
Finally a health forms

↳ Salt marshes often develop in estuaries because…

They are sheltered from strong waves, so sediment (mud and silt) can be deposited
Rivers transport a supply of sediment to the river mouth, which may be added to by sediment flowing into the estuary at high tide

Serial stage	Algal stage	Pioneer stage	Establishment stage	Stabilisation	Climax vegetation
Plants	Blue-green algae Gut weed	Glasswort Cordgrass	Salt marsh grass Sea aster	Sea thrift Scurvy grass Sea lavender	Rush Sedge Red fescue grass
Processes	Grow on and within bare mud, binding it together	Roots begin to stabilise the mid, allowing further mud accretion	A continued carpet of vegetation is established and the salt marsh height increases	This area of the salt marsh is rarely submerged	Developed soil profile and only submerged once or twice each year