water and carbon cycle
Cards (48)
- SystemsComposed 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 systemsSystems that receive inputs and transfer outputs of energy or matter with other systems
- Closed systemsSystems where energy inputs equal outputs
- Dynamic equilibriumWhen inputs equal outputs despite changing conditions
- Positive feedbackA chain of events that amplifies the impacts of the original event
- Negative feedbackA 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
- Inputs in the local water cycle
- Precipitation
- Outputs in the local water cycle
- Evapotranspiration
- Streamflow
- Stores in the local water cycle
- Groundwater
- Soil Water
- Rivers
- Interception
- Surface
- Flows in the local water cycle
- Infiltration
- Percolation
- Throughflow
- Surface Runoff
- Groundwater Flow
- Streamflow
- Stemflow
- Water balanceUsed to express the process of water storage and transfer in a drainage basin system using the formula: Precipitation = Total Runoff + Evapotranspiration +/- Storage
- Factors impacting the local water cycle
- Deforestation
- Storm Events
- Seasonal Changes
- Agriculture
- Urbanisation
- The soil water budget shows the annual balance between inputs and outputs in the water cycle
- There is a surplus of water in the winter months, after recharge of soil water in autumn
- The stores are depleting when evapotranspiration is greater than precipitation, leading to a deficit of soil water
- Maximum storage of water in the soil is field capacity
- Areas where water can be stored globally
- Hydrosphere
- Lithosphere
- Cryosphere
- Atmosphere
- AquifersUnderground water stores that are unevenly distributed globally
- Shallow groundwater aquifers can store water for up to 200 years, but deeper fossil aquifers, formed during wetter climatic periods, may last for 10,000 years
- From accumulation to ablation/calving, glaciers may store water for 20-100 years, which may feed lakes that store water for 50-100 years
- Seasonal snow cover and rivers both store water for 2-6 months, while soil water acts as a more temporary store, holding water for 1-2 months
- Factors affecting the water cycle over time
- Seasonal Changes
- Farming Practices
- Land Use Change
- Water Abstraction
- Flood hydrographUsed to represent rainfall for the drainage basin of a river and the discharge of the same river on a graph
- Factors affecting whether a flood hydrograph will be flashy or subdued
- Pastoral Farming
- Deforestation
- High Rainfall Intensity
- Antecedent Rainfall
- Impermeable Underlying Geology
- High Drainage Density
- The carbon cycle occurs on a local scale in a plant, or sere such as the lithosere, which is a vegetation succession that occurs on bare rock
- Transfers in the global carbon cycle
- Photosynthesis
- Respiration
- Combustion
- Decomposition
- Diffusion
- Weathering and Erosion
- Burial and Compaction
- Carbon Sequestration
- Main carbon stores globally
- Marine Sediments and Sedimentary Rocks
- Oceans
- Fossil Fuel Deposits
- Soil Organic Matter
- Atmosphere
- Terrestrial Plants
- Carbon cycle1. Carbon returned to soil2. Diffusion - oceans absorb CO2 but harms aquatic life3. Weathering and Erosion - rock particles transferred to ocean, carbon used by marine organisms4. Burial and Compaction - shell fragments compacted to form limestone and organic matter to fossil fuels5. Carbon Sequestration - transfer of carbon from atmosphere, natural and artificial
- Main Carbon Stores
- Marine Sediments and Sedimentary Rocks - Lithosphere - Long-term
- Oceans - Hydrosphere - Dynamic
- Fossil Fuel Deposits - Lithosphere - Long-term but currently dynamic
- Soil Organic Matter - Lithosphere - Mid-term
- Atmosphere - Dynamic
- Terrestrial Plants - Biosphere - Mid-term but very dynamic
- The lithosphere is the main store of carbon, with global stores unevenly distributed
- The oceans are larger in the southern hemisphere, and storage in the biosphere mostly occurs on land
- Terrestrial plant storage is focussed in the tropics and the northern hemisphere
- Changes in the Carbon Cycle over time1. Wildfires - transfer carbon from biosphere to atmosphere2. Volcanic Activity - carbon stored within earth released during eruptions
- Human Impacts on the Carbon Cycle1. Fossil Fuel Use - combustion transfers CO2 to atmosphere2. Deforestation - rapidly releases carbon stored in plants3. Farming Practices - arable farming, ploughing, farm machinery release CO2
- Carbon BudgetBalance between carbon inputs and outputs to a store at any scale
- Carbon SourceA store that emits more carbon than it absorbs
- Carbon SinkA store that absorbs more carbon than it emits
- Enhanced Greenhouse EffectProcess causing global warming due to abnormally high levels of greenhouse gases produced by humans, trapping radiation from the sun