water cycle

Created by

freya davies

Cards (127)

Global water stores 
Oceans
Glaciers, ice caps and ice sheets
Groundwater
Surface and other freshwater (permafrost, lakes, swamps, marshes, rivers and living organisms)
Oceans contain 97% of global water
Only 2.5% of global water stores are freshwater
69% of freshwater is in glaciers, ice caps and ice sheets
30% of freshwater is groundwater
Surface and other freshwater only accounts for around 1% of global water stores
Hydrology in Polar Regions 
85% of solar radiation is reflected
Permafrost creates impermeable surfaces
Lakes and rivers freeze
Rapid runoff in spring
Seasonal release of biogenic gases into atmosphere
Orographic and frontal precipitation
Hydrology in Tropical Rainforests 
Dense vegetation consuming 75% of precipitation
Limited infiltration
Deforestation leads to less evapotranspiration and precipitation
Very high temperatures
Very humid
Convectional rainfall
Components of the global water cycle 
Oceans
Icecaps
Groundwater
Rivers and Lakes
Soil moisture
Atmospheric Moisture
Oceans have a residence time of 3600 years
Icecaps have a residence time of 15,000 years
Groundwater has a residence time of 10,000 years
Rivers and lakes have a residence time of 2 weeks to 10 years
Soil moisture has a residence time of 2-50 weeks
Atmospheric moisture has a residence time of 10 days
ITCZ (Inter-tropical Continental Zone) 
The Earth consist of six cells of circulating air, which form the globe's climate control
Hadley Cell - Air rises at The Doldrums, travels upwards, then sinks as it meets the cooler air of the Ferrel Cell. At this meeting point, precipitation tends to occur. The air then travels southwards, heating up as it does. It will then have heated sufficiently to rise up at the Doldrums, commencing the cycle again.
Polar Cell - Cold air sinks near the Arctic Circle, cooling and condensing to form precipitation over northern latitudes. The air then travels southwards, heating until it meets warm air from the Ferrel Cell. The air then rises, causing dry conditions for the land beneath, and then travels northwards, cooling as it does.
Ferrel Cell - The middle cell of the ITCZ (tends to be at a mid-latitude location). The air circulation is determined by the Hadley and Polar cells either side, similar to a cog system.
Drainage basin 
An open subsystem operating within the closed global hydrological cycle. It's defined as an area of land drained by a river and its tributaries with a boundary (known as the watershed), usually composing of hills and mountains.
On a local scale, the water cycle is an open system (a system of processes of water inputs, outputs and throughputs); on a global scale, the water cycle a closed systems (a system that has no inputs or outputs, only throughputs).
The water cycle contains flows/transfers, inputs, outputs and stores/components.
Inputs to the Drainage Basin - Precipitation 
Precipitation is caused by the cooling and condensation of water moisture in the atmosphere, forming clouds that release moisture in the form of rain, snow, hail, sleet, etc.
Factors affecting precipitation 
Seasonality
Variability (Secular, Periodic, Stochastic)
Latitude
Types of Rainfall 
Convectional
Frontal/Cyclonic
Relief/Orographic
Convectional rainfall 
Often a daily occurrence. The morning heat warms the ground, which in turn heats low-level moisture (from plant dew or surface stores). This moisture evaporates and rises. As the air rises, it cools and the moisture within will condense, to form rain and in turn (as more moisture accumulates) rainfall.
Frontal/Cyclonic rainfall 
Where two air masses meet, a wedge can occur of hot air within cold air - this is called a depression. At the front (were the two air masses meet), warm moist air is forced to rise above the cold air mass, causing the water moisture within to cool and condense, to form cyclonic precipitation.
Relief/Orographic rainfall 
When warm, moist air (often travelling onto land from sea) meets land of high relief (e.g. hills), the air mass is forced to rise above the hill to continue travelling. As it rises, the air mass cools and the moisture within condenses, to form clouds and rainfall.
Fluxes and Flows within the Drainage Basin 
Interception - Direct intervention of plants' leaves in changing the direction or temporarily stopping precipitation as it falls to the surface
Infiltration - The movement of water from the surface into the soil
Surface Runoff - Water flows overland, rather than permeating deeper levels of the ground
Throughflow - Water moves through the soil and into streams or rivers
Percolation - Water moves from the ground or soil into porous rock or rock fractures (deeper bedrock and aquifers)
Groundwater Flow - The gradual transfer of water through porous rock, under the influence of gravity
Interception 
The direct intervention of plants' leaves in changing the direction or temporarily stopping precipitation as it falls to the surface. Any moisture retained by the surface of the leaf (interception store) is generally greatest at the start of storms.
Infiltration 
The movement of water from the surface into the soil. The infiltration capacity is the maximum rate at which water can be absorbed by the soil.
Factors affecting infiltration 
Soil Composition
Previous precipitation
Type and amount of vegetation
Compaction of soils
Relief of land
Surface Runoff 
Water flows overland, rather than permeating deeper levels of the ground. Overland flow occurs faster where the gradient of land is greater. Surface runoff if the primary transfer of water to river channels, hence heavily influencing their discharge.
Throughflow 
Water moves through the soil and into streams or rivers. Speed of flow is dependent on the type of soil. Clay soils with a high field capacity and smaller pore spaces have a slower flow rate. Sandy soils drain quickly because they have a lower field capacity, larger pore spaces and natural channels from animals such as worms.
Percolation 
Water moves from the ground or soil into porous rock or rock fractures (deeper bedrock and aquifers). The percolation rate is dependent on the fractures that may be present in the rock and the permeability of the rock.
Groundwater Flow 
The gradual transfer of water through porous rock, under the influence of gravity. Water can sometimes become trapped within these deeper layers of bedrock, creating aquifers and long water stores for the drainage basin.
Outputs of the Drainage Basin 
Evaporation - The direct loss of water moisture from the surface of a body of water, the soil and interception storage (on top of leaves) to the atmosphere
Transpiration - The biological process where water is lost to the atmosphere through the pores of plants (stomata)
Factors influencing evaporation 
Volume and surface area of the water body
Vegetation cover or built environment surrounding the water
The colour of the surface beneath the water
Drainage basin stores 
Soil Water - Water stored in the soil which is utilised by plants
Groundwater - Water that is stored in the pore spaces of rock
River Channel - Water that is stored in a river
Interception - Water intercepted by plants on their branches and leaves before reaching the ground
Surface Storage - Water stored in puddles, ponds, lakes etc.
Water table 
The upper level at which the pore spaces and fractures in the ground become saturated. It is used by researchers to assess drought conditions, health of wetland systems, success of forest restoration programmes etc.
Physical factors influencing the drainage basin 
Climate
Soil Composition
Geology
Relief
Vegetation
Size
Anthropogenic factors influencing the drainage basin 
Cloud seeding
Deforestation
Afforestation
Dam construction
Change in land use
Ground water abstraction
Cloud seeding 
Substances dispersed into the air to provide something for condensation to occur on