water and carbon

Created by

Tegan Ashford

Cards (163)

Systems 
Composed of: Inputs - Where matter or energy is added to the system, Outputs - Where matter or energy leaves the system, Stores - Where matter or energy builds up in the system, Flows - Where matter or energy moves in the system, Boundaries - Limits to the system (e.g. watershed)
Open systems 
Systems that receive inputs and transfer outputs of energy or matter with other systems
Closed systems 
Systems where energy inputs equal outputs
Dynamic equilibrium 
When inputs equal outputs despite changing conditions
Positive feedback 
A chain of events that amplifies the impacts of the original event
Negative feedback 
A chain of events that nullifies the impacts of the original event, leading to dynamic equilibrium
On a local scale the carbon and water cycles are both open systems, but on a global scale, they are closed systems
Each of these systems contains flows/transfers, inputs, outputs and stores/components
Local drainage basin system 
An open system where water may be lost as an output through evapotranspiration and runoff, but more water may be gained as an input through precipitation
Inputs, outputs, flows and stores that drive and cause changes in the water cycle over time
Precipitation
Evapotranspiration
Streamflow
Precipitation 
Any water that falls to the surface of the earth from the atmosphere including rain, snow and hail
Types of rainfall 
Convectional
Relief
Frontal
Evapotranspiration 
Compromised of evaporation and transpiration. Evaporation occurs when water is heated by the sun, causing it to become a gas and rise into the atmosphere. Transpiration occurs in plants when they respire through their leaves, releasing water they absorb through their roots, which then evaporates due to heating by the sun
Streamflow 
All water that enters a drainage basin will either leave through the atmosphere, or through streams which drain the basin
Infiltration 
The process of water moving from above ground into the soil. The infiltration capacity refers to how quickly infiltration occurs
Percolation 
Water moves from the ground or soil into porous rock or rock fractures. The percolation rate is dependent on the fractures that may be present in the rock and the permeability of the rock
Throughflow 
Water moves through the soil and into streams or rivers. Speed of flow is dependent on the type of soil
Surface Runoff (Overland flow) 
Water flows above the ground, as sheetflow (lots of water flowing over a large area), or in rills (small channels similar to streams, that are unlikely to carry water during periods where there is not any rainfall)
Groundwater Flow 
Water moves through the rocks. Ensures that there is water in rivers, even after long period of dry weather
Streamflow 
Water that moves through established channels
Stemflow 
Flow of water that has been intercepted by plants or trees, down a stem, leaf, branch or other part of a plant
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
Water balance 
Used to express the process of water storage and transfer in a drainage basin system and uses the formula: Precipitation = Total Runoff + Evapotranspiration +/- (change in) Storage
The water balance of an area will change dependent on physical factors, especially during seasonal variations of temperature and precipitation
Changes to the water cycle on a local scale
Deforestation
Storm Events
Seasonal Changes
Agriculture
Urbanisation
Pastoral farming 
Farming related to livestock, where livestock such as pigs, cattle, goats, sheep etc, trample the ground reducing infiltration
Arable farming 
Farming related to crops, where ploughing increases infiltration by creating a looser soil, which decreases surface runoff, but digging drainage ditches increases surface runoff and streamflow
Hillside terracing 
Increases surface water storage and therefore decreases runoff
Irrigation 
The movement of water by human intervention through tunnels and other conduits, can lead to groundwater depletion
Impermeable surfaces 
Reduce infiltration but increase surface runoff, reducing lag-time and increasing the flood risk
Green roofs and Sustainable Urban Drainage Systems (SUDS)
Use grass and soil to reduce the amount of impermeable surfaces, helping to tackle the problem of urban flooding in some cities
Soil water budget 
Shows the annual balance between inputs and outputs in the water cycle and their impact on soil water storage/availability
The maximum possible level of storage of water in the soil is field capacity. Once the field capacity is reached, any rainfall after this will not infiltrate the soil and is likely to cause flooding
Seasonal variation of the soil water budget
Autumn - Greater input from precipitation than output from evapotranspiration, soil moisture levels increase and a water surplus occurs
Winter - Potential evapotranspiration from plants reaches a minimum, precipitation continues to refill the soil water stores
Spring - Potential evapotranspiration increases as plants start growing again, there is still a water surplus
Summer - Evapotranspiration peaks and rainfall is at a minimum, soil water stores are depleting and a water deficit may occur
The global water cycle is comprised of many stores, the largest being oceans, which contain 97% of global water. Only 2.5% of stores are freshwater of which 69% is glaciers, ice caps and ice sheets and 30% is groundwater. Surface and other freshwater only accounts for around 1%
In summer 
There is a water surplus
In summer 
The hotter weather leads to utilisation of soil water as evapotranspiration peaks and rainfall is at a minimum
Evapotranspiration output is greater than precipitation input 
Soil water stores are depleting
If there is a long hot summer and spring, a lack of winter rainfall, or a drought the year before
A water deficit may occur