Summary

This document is a set of notes on river environments and the hydrological cycle. Topics covered include the importance of rivers, water usage (agriculture, industry, and domestic), water scarcity and surplus, and the elements of the hydrological cycle. It is suitable for IGCSE Geography students.

Full Transcript

‭River Environments - Syllabus Overview‬ ‭4‬ ‭Lesson 1: Is Water Really A Scarce Resource?‬ ‭Why are River Environments Important?‬ ‭Why do rivers need to be sustainable managed?‬ ‭ ow much water is usable and easily accessible?...

‭River Environments - Syllabus Overview‬ ‭4‬ ‭Lesson 1: Is Water Really A Scarce Resource?‬ ‭Why are River Environments Important?‬ ‭Why do rivers need to be sustainable managed?‬ ‭ ow much water is usable and easily accessible?‬ H ‭Despite water seeming to be an abundant resource,‬ ‭only 3% is freshwater - the rest is saltwater. Out of‬ ‭this, only 0.3% is easily accessible - on the surface of‬ ‭the earth. Most of this water is in rivers and lakes‬ ‭(see diagram).‬ ‭What are the uses of water?‬ ‭‬ ‭Agriculture‬‭: for‬‭irrigation‬‭(supplying water to‬ ‭land or crops to help them grow), drinking‬ ‭water for livestock‬ ‭‬ ‭Industry:‬‭generating electricity (eg: through‬ ‭Hydro-electric power [HEP]‬‭), as a‬‭coolant‬ ‭for industrial processes (eg: manufacturing‬ ‭steel)‬ ‭‬ ‭Human hygiene:‬‭bathing / showering, flushing toilets,‬‭drinking, cooking, washing clothes,‬ ‭washing dishes‬ ‭‬ ‭Leisure:‬‭sailing on lakes and ponds, watering golf‬‭courses, sport fishing on rivers,‬ ‭watering gardens‬ ‭‬ ‭Global water use by sector is:‬ ‭○‬ ‭70% agriculture - irrigation of crops and water for livestock‬ ‭○‬ ‭20% industry - producing goods and generating energy‬ ‭○‬ ‭10% domestic - toilets, cooking, cleaning, washing‬ ‭How does the use of water vary around the world?‬ ‭‬ ‭The use by sector varies across countries depending on whether they are‬‭developed,‬ ‭emerging or developing‬‭(see class activity notes you‬‭made below and the online‬ ‭powerpoint in class files for the maps; you should review the maps so that you can practise‬ ‭the skills stated in the syllabus).‬ ‭CONTINUES ON NEXT PAGE‬ ‭5‬ ‭Figure 1:‬‭Which countries use the most amount of water?‬‭Why?‬ ‭Examples of countries‬ ‭Reason‬ ‭Figure 1:‬‭Which countries use the least amount of‬‭water? Why?‬ ‭Examples of countries‬ ‭Reason‬ ‭Figure 2, 3 and 4:‬‭Which countries use water for the‬‭following the most?‬ ‭Agriculture‬ ‭Industry‬ ‭ omestic use‬ D ‭(leisure and human‬ ‭hygiene)‬ ‭Figure 5:‬‭Which countries have‬‭water shortages‬‭? Why?‬ ‭Examples of countries‬ ‭Reason‬ ‭CONTINUES ON NEXT PAGE‬ ‭6‬ ‭Figure 5:‬‭Which countries may have a‬‭water surplus‬‭?‬‭Why?‬ ‭Examples of countries‬ ‭Reason‬ ‭Figure 6:‬‭How has the use of freshwater changed over‬‭time? Why?‬ ‭Trend‬ ‭Reason‬ ‭Key Terms & Definitions:‬ ‭‬ ‭Water abstraction‬‭- water removed from any sources‬‭(commonly: lakes, rivers, aquifers‬ ‭and reservoirs).‬ ‭○‬ ‭Aquifers‬‭are rock and/or sediment that holds water.‬‭The water that is held in‬ ‭aquifers is known as‬‭groundwater‬‭.‬ ‭○‬ ‭A‬‭reservoir‬‭is a large natural or artificial lake‬‭used as a source of water supply.‬ ‭‬ ‭Water demand‬ ‭- this is the volume of water‬‭requested‬‭by users to satisfy their needs.‬ ‭‬ ‭Water consumption‬‭- this is the amount of water that‬‭is no longer available for use.‬ ‭‬ ‭Water supply‬‭is the‬‭portion of abstracted water that‬‭is delivered to users‬‭, excluding any‬ ‭losses that occur during storage, transport, or distribution.‬ ‭‬ ‭Water stress‬‭refers to the‬‭amount of freshwater extracted‬‭as a percentage of available‬ ‭freshwater resources‬‭.‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.3: River environments are of great importance to people and need to be‬ ‭sustainably managed‬ ‭‬ ‭Section 1.3 (a): Uses of water, including agriculture, industry, human hygiene and leisure,‬ ‭and the rising demand for and supply of water: areas of water shortage and water surplus.‬ ‭‬ ‭Skill: use different maps (paper or online) to investigate the impact of human intervention.‬ ‭7‬ ‭Lesson 2: Where Does Our Freshwater Really Come From In the Hydrological Cycle?‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.1: The world’s water supply is contained in a closed system – the hydrological‬ ‭cycle.‬ ‭‬ ‭Section 1.1 (a): The hydrological cycle: characteristics, stores and transfers.‬ ‭ ctivity 1:‬‭After we discuss this in class, (i) highlight‬‭stores‬‭in one colour and‬‭transfers‬‭in‬ A ‭another colour and (ii) label if water is stored as a solid, liquid or gas gas in every store.‬ ‭ ctivity 2:‬‭How would the following affect the water‬‭cycle?‬ A ‭Draw a flowchart to show the changes, using as many key terms from the hydrological cycle as‬ ‭you can!‬ ‭A‬ B ‭ uilding artificial‬ ‭reservoirs‬ ‭B‬ D ‭ raining water‬ ‭from wetlands to‬ ‭build cities‬ ‭C‬ U ‭ sing water from‬ ‭rivers, lakes and‬ ‭aquifers for homes‬ ‭D‬ ‭Deforestation‬ ‭E‬ D ‭ ry season - lack‬ ‭of rainfall‬ ‭F‬ ‭ elting glaciers‬ M ‭and ice sheets‬ ‭8‬ ‭ he‬‭Hydrological Cycle‬‭(also known as the water cycle)‬‭is a continuous movement and‬ T ‭circulation of water on Earth.‬ ‭Characteristics:‬ ‭‬ ‭It is a‬‭closed system‬‭: this means that there is a‬‭fixed amount of water within the system‬ ‭and water is recycled as it moves through it. This is because water does not enter or leave‬ ‭the atmosphere.‬ ‭‬ ‭It is a‬‭global circulation‬‭of water.‬ ‭‬ ‭Within this system, water changes its state and can be seen in solid (‬‭ice‬‭), liquid (water)‬ ‭and gaseous (‬‭water vapour‬‭) form.‬ ‭‬ ‭The hydrological cycle has‬‭transfers / flows‬‭and‬‭stores;‬‭it does‬‭not‬‭include inputs or‬ ‭outputs as it is a closed system.‬ ‭‬ ‭Stores‬‭are places where water is held for a period‬‭of time. These include:‬ ‭○‬ ‭Atmosphere:‬‭clouds (water is as water vapour or liquid‬‭water droplets)‬ ‭○‬ ‭Land:‬‭puddles, lakes, rivers,‬‭reservoirs‬‭, vegetation,‬‭soil, ice-sheets, glaciers,‬ ‭aquifers‬‭.‬ ‭‬ ‭Aquifers‬‭are rock and/or sediment that holds water.‬‭The water that is held‬ ‭in aquifers is known as‬‭groundwater‬‭.‬ ‭‬ ‭A‬‭reservoir‬‭is a large natural or artificial lake‬‭used as a source of water‬ ‭supply‬‭.‬ ‭‬ ‭Interception‬‭is how precipitation is prevented from‬‭reaching the ground and‬ ‭hence is stored. This is usually by precipitation being caught on leaves or‬ ‭branches, or in puddles.‬ ‭○‬ ‭Sea: oceans and icebergs.‬ ‭○‬ ‭Note: whilst the amount of water in the hydrological cycle remains the same, the‬ ‭amount of water held in each‬‭store‬‭can.‬ ‭‬ ‭Transfers / flows‬‭are the ways in which water is moved‬‭around the hydrological cycle.‬ ‭ ctivity 3:‬‭(1) Label the types of transfers / flows‬‭in the diagram below. (2) Which types of flows‬ A ‭are missing? Label these, using an arrow to show the direction of flow‬ ‭9‬ ‭Transfers / Flows‬‭in the Hydrological Cycle‬ ‭Activity 4:‬‭match the key term with the correct definition.‬ ‭Transfer / Flow‬ ‭Definition‬ ‭A‬ ‭Evaporation‬ ‭ lants take up liquid water from the soil and release this water as‬ P ‭water vapour from its leaves to the atmosphere.‬‭(Hint‬‭to‬ ‭remember it: plants ‘breathe’ the water back into the atmosphere).‬ ‭B‬ ‭Infiltration‬ ‭ ater vapour cools and changes into its liquid form (water). This‬ W ‭can happen in the atmosphere (eg: clouds are formed as a‬ ‭collection of water droplets) or at ground level (eg: dew).‬ ‭C‬ ‭Evapotranspiration‬ ‭ ater is converted from liquid to a gas (water vapour) by the heat‬ W ‭of the sun. This takes place in areas such as the sea, lakes, rivers‬ ‭and soil. The water vapour is stored in the atmosphere.‬ ‭D‬ ‭Condensation‬ ‭ orizontal‬‭movement of water through rocks in the‬‭aquifer. The‬ H ‭water can eventually reach rivers, lakes and the sea.‬ ‭E‬ ‭Transpiration‬ ‭ his is the combined transfer of water from the earth’s surface‬ T ‭(through evaporation) and plants (through transpiration).‬ ‭F‬ ‭Precipitation‬ ‭ ater moves‬‭vertically into the surface‬‭of the land‬‭.‬ W ‭(Hint: it “infiltrates” the soil)‬ ‭G‬ G ‭ roundwater flow‬ ‭ ovement of water‬‭vertically through the soil itself‬‭.‬‭This can be,‬ M ‭/ Base flow‬ ‭for example, through the soil and into the groundwater store /‬ ‭aquifers.‬ ‭H‬ O ‭ verland flow /‬ ‭ iquid or solid water that falls to Earth as a result of condensation‬ L ‭runoff‬ ‭in the atmosphere. This includes rain, snow, and hail.‬ ‭I‬ ‭Percolation‬ ‭ here is more water than the soil can absorb so the water moves‬ T ‭over the surface of the soil‬‭(hint: “runs off”)‬‭. This‬‭water can move‬ ‭faster down slopes due to gravity and is eventually absorbed by‬ ‭nearby rivers, lakes or sea.‬ ‭J‬ ‭Throughflow‬ ‭ ater enters a‬‭river or stream‬‭and moves through this.‬ W ‭(Hint: the flow is confined within a channel).‬ ‭K‬ ‭Canopy drip‬ ‭ recipitation (eg: rainfall) reaching the ground in a forest by‬ P ‭draining down the trunks of trees or stems of plants.‬ ‭L‬ C ‭ hannel flow /‬ ‭ recipitation drips off the leaves and branches of trees and plants‬ P ‭river flow‬ ‭onto the ground or plants below.‬ ‭M‬ ‭Stem flow‬ ‭ orizontal‬‭movement of water‬‭through‬‭the soil.‬‭It‬‭can eventually‬ H ‭reach a stream or river through the soil.‬ ‭10‬ ‭Lesson 3: How do the Drainage Basins Ignite Water Wars?‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.1(b): Features of a drainage basin: source, watershed, channel network, mouth.‬ ‭ ‬‭drainage basin‬‭is an entire river‬ A ‭system and the surrounding land that‬ ‭influences the river system—it is the area‬ ‭drained by a river and its tributaries. It is‬ ‭also known as a‬‭catchment area‬‭or‬‭river‬ ‭basin‬‭.‬ ‭ ‬‭watershed‬‭is the high land that forms‬ A ‭the boundary of a river drainage basin. It‬ ‭usually separates two drainage basins,‬ ‭but there are exceptions. For example,‬ ‭the drainage basins of smaller tributaries‬ ‭are included within the drainage basins of‬ ‭larger rivers.‬ ‭ he‬‭features‬‭(which are the visible forms)‬ T ‭of a drainage basin, include:‬ ‭‬ ‭Source‬‭- where a river begins (eg:‬ ‭an upland lake,‬‭spring‬‭or‬‭glacier‬‭).‬ ‭○‬ ‭A‬‭spring‬‭is a point on land where groundwater from‬‭aquifers rises up to the‬ ‭surface.‬ ‭‬ ‭Mouth‬‭- where a river meets a larger body of water‬‭(eg: a lake, sea, reservoir)‬ ‭‬ ‭Confluence‬‭- the point at which two streams or rivers‬‭meet.‬ ‭‬ ‭Tributary‬‭- a small river or stream that joins a larger‬‭river.‬ ‭‬ ‭Channel‬‭- this is where the river flows.‬ ‭‬ ‭Drainage network‬‭: the pattern of tributaries and rivers‬‭within a drainage basin.‬ ‭○‬ ‭Drainage density:‬‭this is the total number of channels‬‭divided by the total area of‬ ‭the drainage basin.‬ ‭‬ ‭Drainage basins with lots of channels have a high drainage density‬ ‭‬ ‭Drainage basins with few channels have a low drainage density‬ ‭○‬ ‭Drainage densities are affected by a number of factors:‬ ‭‬ ‭During times of drought, rainfall reduces and channel flow reduces. This‬ ‭reduces the drainage density.‬ ‭‬ ‭During summer, when snow melts, there is more channel flow, which‬ ‭increases the drainage density.‬ ‭‬ ‭Open system -‬‭this means that the drainage basin has‬‭inputs‬‭(water coming in; for‬ ‭example: by precipitation)‬‭and outputs‬‭(water released‬‭out; for example: to the sea or‬ ‭atmosphere). As a result, the amount of water in a drainage basin would vary over time.‬ ‭○‬ ‭Avoid a common error:‬‭the hydrological system is a‬‭closed system (no inputs and‬ ‭outputs). The drainage basin is an open system.‬ ‭Activity 1:‬ ‭‬ ‭Task 1: On Figure A, label: (i) mouth, (ii) confluence, (iii) tributary, and (iv) channel.‬ ‭‬ ‭Task 2: Figure A shows a drainage basin with labels of some processes that take place‬ ‭in this region. Highlight each of the following in different colours: (a) transfers, (b) stores,‬ ‭(c) inputs and (d) outputs.‬ ‭11‬ ‭‬ T ‭ ask 3: Are there any stores, transfers, inputs or outputs that are not labelled? Label‬ ‭these as well!‬ ‭Figure A: Diagram of a drainage basin and the process that are happening within it‬ ‭12‬ ‭Lesson 4: Can you read a Storm Hydrograph?‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Integrated Skills: Draw and interpret storm hydrographs using rainfall and discharge data.‬ ‭Recall Activity: Drainage Basins & Data Analysis Practice‬ ‭Figure A‬ ‭(i) On Figure A, mark the following:‬ ‭(a)‬ ‭Confluence that is closest to Bostcastle‬ ‭(b)‬ ‭Tributary of the River Valency that is closest to Bostcastle‬ ‭(c)‬ ‭Mouth of the River Valency‬ ‭(ii) Is Boscastle part of the drainage basin of the River Valency? Explain your choice.‬ ‭Yes it is as it makes up the mainstem drainage basin. Mainstem = valency‬ ‭-https://education.nationalgeographic.org/resource/tributary/‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭Questions continue on next page‬ ‭14‬ ‭Figure B: Rainfall and River data collected at Boscastle‬ ‭(iii) According to Figure B:‬ (‭ a) What is the rainfall at 13:30 hours?...............................................................................................‬ ‭(b) What is the amount of water flowing in the river at 13:30 hours?..................................................‬ ‭(c) At what time is the rainfall the highest?.........................................................................................‬ ‭(d) When does the rainfall in Boscastle stop?....................................................................................‬ ‭(e) How does the amount of water in the river at Boscastle change between 12:30 and 20:00?‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ (‭ f) Why is there a gap in time between the rainfall at Boscastle and the amount of water flowing in‬ ‭the river at Boscastle? (Hint: steps in the water cycle…)‬ ‭ ime for the water to flow (throughflow - takes time, runoff - fastest, groundwater flow - slowest).‬ T ‭Interception (puddles, vegetation, obstructions on the ground)‬ ‭End of Questions‬ ‭15‬ ‭ nalysing a Storm Hydrograph‬ A ‭A river’s‬‭discharge‬‭refers to the amount of water‬‭that passes a given point on a stream or river‬ ‭within a given period of time. It is measured in cubic metres a second (‬‭cumecs‬‭)‬ ‭ ‬‭storm hydrograph‬‭shows the changes in river discharge‬‭before, during and after a storm event.‬ A ‭It is one graph with the variations in a river’s discharge (as a line graph) and rainfall (as a bar‬ ‭graph) over time shown on it. The time that it usually covers is just the time taken for a storm to‬ ‭pass (a few hours or days). An example is shown below:‬ ‭‬ ‭Base flow‬‭- this is the usual discharge of the river.‬ ‭○‬ ‭If there is no input to the drainage basin of a river, the water would be at base flow.‬ ‭‬ ‭Peak rainfall‬‭- highest rainfall during a storm.‬ ‭‬ ‭Rising limb‬‭- shows the rise in the discharge of‬‭a river during a storm. The steepness of‬ ‭the rising limb indicates how quickly the discharge increases.‬ ‭‬ ‭Peak discharge‬‭- highest level of discharge.‬ ‭‬ ‭Lag time‬‭- the time difference between peak rainfall‬‭and peak discharge. There is a delay‬ ‭between these because it takes time for the water to find its way to the river.‬ ‭○‬ ‭A shorter time lag occurs when the water reaches the river more quickly.‬ ‭‬ ‭Recessional limb‬‭- the river discharge returns back‬‭to usual levels (base flow) as the‬ ‭extra water brought by the storm moves downstream or infiltrates the ground. A steep‬ ‭falling limb suggests that water is leaving the drainage basin quickly.‬ ‭○‬ ‭Note that the falling limb shows that water is still reaching the river but in‬ ‭decreasing amounts.‬ ‭‬ ‭Bankfull‬‭- The water level at a stream, river or lake‬‭is at the top of its banks and any‬ ‭further rise would result in water moving over its banks onto the land around it‬ ‭‬ ‭Storm flow -‬‭the additional discharge of the river‬‭directly related to the passing of the‬ ‭rainstorm.‬ ‭ hydrograph shows you the ways in which a river is affected by a storm. This helps us to‬ A ‭understand discharge patterns of a particular drainage basin, which in turn helps to predict‬ ‭flooding and plan flood prevention measures.‬ ‭16‬ ‭Knowledge-Check‬ ‭ igure B: Rainfall and River data collected at Boscastle‬ F ‭(iv) According to figure B above:‬ ‭(a)‬ ‭What is the peak rainfall?.......................................................................................................‬ ‭(b)‬ ‭What is the peak discharge?..................................................................................................‬ ‭(c)‬ ‭How long is the lag time in Figure B? Show your working.‬ (‭ d)‬ ‭Is the rising limb or the recessional limb steeper?..................................................................‬ ‭(e)‬ ‭Using Figure A and B, explain why the discharge in the river decreases back to base flow.‬ ‭…………………………………………………………………………………………………………………..‬ ‭………………………………………………………………………………………………………………….‬ ‭(f)‬ ‭What is the percentage increase in water level from 12.30 to 18.00? Show your working.‬ ‭(g)‬ ‭What is the percentage decrease in water level from 18.0 to 20.00? Show your working.‬ ‭(v) Draw a storm hydrograph on graph paper to show the following data.‬ ‭17‬ ‭ ctivity 1:‬‭Which river is more likely to flood during‬‭a storm?‬ A ‭A river floods when it has too much water to hold, causing the water to overflow from its‬‭banks‬‭(a‬ ‭bank is the side of a river).‬ ‭ ydrographs for different‬ H ‭ he river that is most‬ ‭Explanation for your choice‬ T ‭scenarios.‬‭Peak rainfall‬ ‭likely to flood…‬ ‭occurs at the start of the‬ ‭(select the correct‬ ‭x-axis for all graphs.‬ ‭answer)‬ ‭ as a large‬ H ‭ large drainage basin is able to hold‬ A ‭drainage basin‬ ‭more water (greater channel flow). This‬ ‭Has a small‬ ‭increases the capacity of a river - so the‬ ‭drainage basin‬ ‭river would take a longer time to reach‬ ‭bankfull discharge.‬ ‭ as a forested‬ H ‭ egetated land increases interception -‬ V ‭vegetation in its‬ ‭which reduces overland flow and‬ ‭drainage basin‬ ‭throughflow. This in turn reduces storm‬ ‭Has bare land (no‬ ‭flow and the risk of bankfull discharge.‬ ‭vegetation) in its‬ ‭drainage basin‬ ‭ as gentle valleys‬ H ‭ teep valley sides increase overland‬ S ‭surrounding the‬ ‭flow and reduce infiltration - which‬ ‭river‬ ‭increases storm flow and the risk of‬ ‭Has steep valley‬ ‭bankfull discharge.‬ ‭slopes surrounding‬ ‭the river‬ ‭ as‬‭permeable‬ H I‭mpermeable rock prevents infiltration‬ ‭(allows liquids or‬ ‭and increases overland flow - which‬ ‭gases to pass‬ ‭increases storm flow and the risk of‬ ‭through)‬‭rock in its‬ ‭bankfull discharge.‬ ‭drainage basin‬ ‭Has‬‭impermeable‬ ‭(does not allow‬ ‭liquids or gases to‬ ‭pass through)‬‭rock‬ ‭in its drainage basin‬ ‭18‬ ‭Activity 2‬ ‭Column 1‬ ‭Column 2‬ ‭Column 3‬ ‭Factor‬ ‭ an this increase‬ C ‭Explain your answer in column 2‬ ‭the risk of a river‬ ‭flooding? (yes / no)‬ ‭ ow drainage‬ L ‭ his reduces channel flow and increases the risk‬ T ‭density‬ ‭of bankfull discharge.‬ ‭ igh amount of‬ H ‭ his increases overland flow and throughflow -‬ T ‭rainfall‬ ‭which contributes to storm flow and increases the‬ ‭risk of bankfull discharge.‬ ‭ nowstorm (not a‬ S ‭ ater is stored in its solid form on soil and‬ W ‭rainstorm)‬ ‭vegetation. This reduces channel flow and storm‬ ‭flow.‬ ‭ rtificial drainage‬ A ‭ rainage systems that connect to the soil‬ D ‭system in cities that‬ ‭increase infiltration and percolation - leading to‬ ‭connect to soil and‬ ‭storage of water as groundwater. This can also‬ ‭canals‬ ‭lead to throughflow - which increases the risk of‬ ‭storm flow.‬ I‭f the drains connect to canals, this can increase‬ ‭channel flow and increase the risk of bankfull‬ ‭discharge.‬ ‭ iver is next to a‬ R ‭ here is increased overland flow and less‬ T ‭road and pavement‬ ‭infiltration as the ground is impermeable. This‬ ‭increases storm flow and the risk of bankfull‬ ‭discharge.‬ ‭ iver has many‬ R ‭ ater can be stored in lakes and reservoirs. This‬ W ‭lakes and reservoirs‬ ‭reduces channel flow and storm flow.‬ ‭ longated basin‬ E ‭ hannel flow is faster and this reduces bankfull‬ C ‭shape (left on the‬ ‭discharge.‬ ‭diagram below)‬ ‭19‬ ‭Lesson 5: River Regimes: What Forces Control the Rise and Fall of a River's Waters?‬ ‭ ast lesson, we looked at the variation in discharge due to a short-term cause such as a storm. This‬ L ‭lesson is focused on a river regime.‬ ‭ ‬‭river‬‭regime‬‭is the seasonal variation in the discharge‬‭in the river over the course of a year‬‭. It‬ A ‭takes into account factors such as precipitation, temperature, and the features of the surrounding‬ ‭landscape. River regimes can be shown on an‬‭annual‬‭hydrograph‬‭or a map.‬ ‭Figure A: River in Turkey‬ ‭Figure B: River in England‬ ‭ he area has hot, arid summers but there can‬ T ‭ he drainage basin is flat (no steep slopes),‬ T ‭be intense downpours of rain during the winter.‬ ‭covered in vegetation and the rock underneath‬ ‭The rock underneath this drainage basin is‬ ‭the soil is permeable chalk. A‬‭dam‬‭is also in this‬ ‭impermeable chalk.‬ ‭area to control the flow of water - it stores water‬ ‭in a‬‭reservoir‬‭during droughts and lets it out‬ ‭during floods.‬ ‭ igure C: River in Canada‬ F ‭Figure D: River in the Sahara desert‬ ‭The drainage basin contains glaciers and‬ ‭ T he climate is very dry so river levels are very‬ ‭snowfields. Snow falls in the winter and melts in‬ l ‭ ow or non-existent. It only rains occasionally,‬ ‭the summer.‬ ‭but when it does rain it rains a lot in a short‬ ‭period of time.‬ ‭Glossary‬ ‭‬ ‭Reservoir‬‭: a large natural or artificial lake used‬‭as a source of water supply.‬ ‭20‬ ‭‬ D ‭ am‬‭: a barrier constructed to hold back water and‬‭raise its level, forming a reservoir. Dams‬ ‭also have a gate which can control the amount of water in the reservoir by letting out‬ ‭excess water.‬ ‭‬ ‭Water abstraction‬‭: (taking water from rivers, lakes,‬‭and aquifers for various uses, such as‬ ‭drinking, irrigation, and industrial cooling)‬ ‭ hy are the river regimes different for the locations shown in Figure A-D? Complete the table‬ W ‭below with your responses. One reason is completed for you as an example.‬ ‭Reason‬ ‭Explanation‬ ‭ ater‬ W ‭ he river regime for the river in the Sahara desert shows a sharp drop in discharge‬ T ‭ bstraction‬ ‭every time it rises. This is because the water is scarce in a desert environment and‬ a ‭ ence the people living there would extract any water available for their own use (eg:‬ h ‭ rinking, washing clothes). Further, the overall discharge is low as groundwater is‬ d ‭ xtracted for use, which reduces groundwater flow.‬ e ‭Climate‬ ‭21‬ ‭Figure E‬ ‭ omework Question:‬ H ‭Using Figure E, analyse why the storm hydrographs of Clapham Beck and Austwick Beck are so‬ ‭different.‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.1(c): Factors affecting river regimes: precipitation, including storm hydrographs,‬ ‭temperature, vegetation, land use, water abstraction, dams.‬ ‭‬ ‭Integrated Skills: Draw and interpret storm hydrographs using rainfall and discharge data.‬ ‭22‬ ‭Lesson 6: How Do Erosion, Transportation, and Deposition Transform Rivers?‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.2(a): Fluvial processes involved in river valley and river channel formation:‬ ‭erosion (vertical and lateral), weathering and mass movement, transportation and‬ ‭deposition, and factors affecting these processes (climate, slope, geology, altitude and‬ ‭aspect).‬ ‭ ivers change the shape of drainage basins, primarily through the‬‭fluvial processes‬‭:‬‭erosion,‬ R ‭transportation, deposition‬‭,‬‭weathering‬‭and‬‭mass movement‬‭.‬ ‭Glossary‬ ‭‬ ‭Fluvial‬‭- relating to rivers‬ ‭○‬ ‭River bed‬‭- bottom of the river‬ ‭○‬ ‭River bank‬‭- sides of the river‬ ‭‬ ‭Erosion‬‭is the process in which earthen materials‬‭are worn away and transported by‬ ‭natural forces such as water.‬ ‭○‬ ‭Erosion can occur as a result of wind and ice as well; you will learn about this later.‬ ‭‬ ‭Weathering‬‭is the breaking down or dissolving of rocks‬‭and minerals on the surface of‬ ‭Earth. The broken down segments remain where they are.‬ ‭‬ ‭Mass Movement - movement of material down a slope.‬ ‭‬ ‭Transportation‬‭is the way in which rivers carry material‬‭(known as‬‭load)‬‭from one place to‬ ‭another‬ ‭‬ ‭Deposition‬‭is the process in which earthen materials‬‭are left behind, or built up, on a‬ ‭landform.‬ ‭‬ ‭Load‬‭- includes: (1) material that has fallen into‬‭the river and (2) material which has been‬ ‭eroded by the river from its banks and bed.‬ ‭○‬ ‭Bedload‬‭: material at the bed of a river‬ ‭○‬ ‭Alluvium‬‭: this is a loose, fertile soil or sediment‬‭made up of sand, silt, clay, and‬ ‭gravel. It is formed due to erosion at the upper course of rivers and is deposited by‬ ‭rivers and river floods in other landscapes (eg: a floodplain).‬ ‭‬ ‭Aspect‬‭- this refers to the direction in which a slope‬‭faces. It can also refer to the physical‬ ‭features of a river (eg: a waterfall, the bends in a river) etc.‬ ‭○‬ ‭Meander‬‭- this is a bend in a river.‬ ‭How does Erosion Happen in Rivers?‬ ‭There are four main types of erosion:‬ ‭‬ ‭Hydraulic action‬‭is the wearing‬ ‭away of rocks in‬‭two ways‬‭:‬ ‭(1)‬ ‭As the water rushes along, it slams‬ ‭against the river’s banks and bed,‬ ‭constantly hitting and grinding‬ ‭against the rocks and soil. This‬ ‭force alone can wear the land‬ ‭down over time.‬ ‭(2)‬ ‭River rocks often have cracks in‬ ‭them. As the river water flows, it‬ ‭pushes air and some water into‬ ‭these cracks. When this happens,‬ ‭the air and water trapped inside the cracks get compressed, which puts pressure on the‬ ‭rock. Over time, this pressure can cause the rock to crack‬ ‭23‬ ‭‬ A ‭ brasion‬‭- when rocks and other materials carried by the water scrape against a surface‬ ‭(such as the‬‭bed‬‭or the‬‭banks‬‭of a river), wearing‬‭it down over time.‬ ‭‬ ‭Attrition‬‭- when rocks that the river is carrying‬‭knock against each other. They break apart‬ ‭to become smaller and more rounded.‬ ‭‬ ‭Solution / Corrosion‬‭- when the flowing water dissolves‬‭certain types of rocks, eg‬ ‭limestone.‬ ‭The four types of erosion above can erode a drainage basin either vertically or laterally:‬ ‭‬ ‭Vertical erosion‬‭increases the depth of the river‬‭as the river erodes downwards‬ ‭‬ ‭Lateral erosion‬‭increases the width of the river as‬‭it erodes sideways‬ ‭ ow is this Eroded Material Transported in Rivers?‬ H ‭There are four types of transportation that‬ ‭happen in rivers:‬ ‭‬ ‭Traction‬‭- large, heavy pebbles are‬ ‭rolled along the river bed. This is most‬ ‭common near the source of a river, as‬ ‭here the load is larger.‬ ‭Note that traction in the dictionary means: the‬ ‭action of pulling something over a surface.‬ ‭‬ ‭Saltation‬‭- pebbles are bounced along‬ ‭the river bed, most commonly near the‬ ‭source.‬ ‭Note that saltation in the dictionary means the‬ ‭action of leaping or jumping.‬ ‭‬ ‭Suspension‬‭- lighter sediment is carried‬ ‭(suspended) within the water, most commonly near the mouth of the river.‬ ‭‬ ‭Solution‬‭- the transport of dissolved minerals and‬‭chemicals.‬ ‭24‬ ‭How Does Deposition Happen?‬ ‭‬ ‭When a river does not have enough energy to carry materials it drops them; in other words,‬ ‭deposition occurs.‬ ‭‬ ‭The heaviest material is deposited first, this is known as the‬‭bedload.‬‭The lighter materials‬ ‭(eg:‬‭alluvium‬‭) are carried further downstream to be‬‭deposited. The dissolved materials are‬ ‭carried out to sea.‬ ‭ hy does deposition occur?‬ W ‭Complete the table below to show how deposition occurs at various places and times:‬ ‭At certain locations such as…‬ ‭ t the inner bend of a river‬ A ‭ here T is a narrow space for the water to flow at the bend → less‬ ‭(eg:‬‭meander‬‭)‬ ‭ ater w flows at the bend → so the river has less energy → river‬ ‭water drops material (deposition)‬ ‭At the mouth of the river‬ ‭River bed and banks‬ ‭Friction‬ ‭ entle sloping river cross‬ G ‭profiles at the lower course‬ ‭Reduces speed of flow‬ ‭During certain times such as…‬ ‭Lack of precipitation‬ ‭Abstraction upstream‬ ‭25‬ ‭Debate Preparation:‬ ‭CLIMATE‬ ‭SLOPE‬ ‭Erosion‬ ‭Erosion‬ ‭Transportation‬ ‭Transportation‬ ‭Deposition‬ ‭Deposition‬ ‭GEOLOGY‬ ‭ASPECT‬ ‭Erosion‬ ‭Erosion‬ ‭Transportation‬ ‭Transportation‬ ‭Deposition‬ ‭Deposition‬ ‭ALTITUDE‬ ‭A reason of your choice:‬ ‭Erosion‬ ‭Erosion‬ ‭Transportation‬ ‭Transportation‬ ‭Deposition‬ ‭Deposition‬ ‭26‬ ‭Lesson 7: How Do Weathering and Mass Movement Sculpt Rivers?‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.2(a): Fluvial processes involved in river valley and river channel formation:‬ ‭erosion (vertical and lateral), weathering and mass movement, transportation and‬ ‭deposition, and factors affecting these processes (climate, slope, geology, altitude and‬ ‭aspect).‬ ‭Recall:‬ ‭‬ ‭What is the difference between weathering and erosion?‬ ‭ eathering‬ W ‭There are three types of weathering:‬ ‭‬ ‭Physical weathering‬‭- rocks are broken down into smaller‬‭pieces without any changes to‬ ‭its chemical composition. Rocks are broken down by rain, wind and other atmospheric‬ ‭processes.‬ ‭ xample of‬ E ‭Explanation of Process‬ ‭Physical‬ ‭Weathering‬ ‭Freeze-thaw‬ I‭n a cold climate, liquid water‬ ‭seeps into cracks in a rock and‬ ‭freezes into ice. When water‬ ‭freezes as ice, it expands,‬ ‭which slowly widens the cracks‬ ‭and splits the rock. As the‬ ‭temperature increases (eg:‬ ‭during daytime), the ice melts‬ ‭into liquid water, which can‬ ‭seep through the cracks in‬ ‭rocks again for the process to‬ ‭start again.‬ ‭Exfoliation‬ ‭ he outer layers of rock expands when exposed to high temperatures during‬ T ‭the day and contracts when exposed to low temperatures at night. As this‬ ‭happens over and over again, the structure of the rock weakens. Over time, the‬ ‭outer layers flake off.‬ ‭‬ C ‭ hemical weathering‬‭- rocks are weakened and broken‬‭down due to chemical reactions‬ ‭that change the molecular structure of rocks.‬ ‭○‬ ‭For example:‬‭carbonation.‬‭This is when carbon dioxide‬‭from the air or soil‬ ‭combines with water to produce a weak acid, called‬‭carbonic acid‬‭, that can‬ ‭dissolve rock. Carbonic acid is especially effective at dissolving‬‭limestone‬‭.‬ ‭‬ ‭Biological weathering‬‭- rocks are weakened and broken‬‭down by living organisms and‬ ‭their processes.‬ ‭ gent of‬ A ‭Explanation of Process‬ ‭Biological‬ ‭Weathering‬ ‭27‬ ‭Plant‬ ‭ he seed of a tree may sprout in soil that has collected in a cracked rock. As the‬ T ‭roots grow, they widen the cracks, eventually breaking the rock into pieces. Over‬ ‭time, trees can break apart even large rocks.‬ ‭Animals‬ ‭ nimals, such as moles, dig underground and trample rock aboveground,‬ A ‭causing rock to slowly crumble.‬ ‭ ass Movement‬ M ‭There are a number of types of mass movement, but in river valleys there are two main types:‬ ‭Type‬ ‭Slumping (Rotational Slide)‬ ‭Soil Creep‬ ‭Definition‬ ‭ lumping‬‭is when a‬‭huge section‬‭of‬ S S ‭ oil Creep‬‭is the‬‭slow‬‭and‬‭steady‬ ‭the river bank or valley‬‭slides rapidly‬ ‭downward movement‬‭of the‬‭upper‬ ‭along a‬‭curved‬‭slope.‬ ‭layers‬‭of the soil on a slope.‬ ‭Causes‬ ‭ here are two main causes that‬ T ‭ his happens because the material is‬ T ‭occur together or at different times:‬ ‭constantly under a small amount of‬ ‭(1)‬ ‭The bottom of a valley or the river‬ ‭stress that causes it to slowly change‬ ‭bank is eroded by the water‬ ‭shape over time, without breaking‬ ‭flowing against it. This makes the‬ ‭apart.‬ ‭slope unstable and the overlying‬ ‭material slides down.‬ ‭ or instance, when soil is saturated‬ F ‭(2)‬ ‭Heavy rain on the slope:‬ ‭with water, it expands outward and‬ ‭(a)‬ ‭makes the soil on top heavier‬ ‭becomes more compact. When the soil‬ ‭so that it slides down‬ ‭dries, it contracts and loosens, causing‬ ‭(b)‬ ‭makes it easier for the soil to‬ ‭the material to be pulled down the‬ ‭slide by acting as a lubricant‬ ‭slope slightly under the influence of‬ ‭gravity. Over many wetting-drying‬ ‭cycles, the soil moves slowly down the‬ ‭slope.‬ ‭Diagram‬ ‭28‬ ‭Picture‬ ‭ oil creep is the slowest of all mass‬ S ‭movements, with movement less than a‬ ‭centimetre per year. However, there are‬ ‭signs of soil creep over time: as the soil‬ ‭creeps downward, it can tilt trees and‬ ‭poles and bend straight fences.‬ ‭29‬ ‭Final Debate Preparation:‬ ‭CLIMATE‬ ‭SLOPE‬ ‭Weathering‬ ‭Weathering‬ ‭Mass Movement‬ ‭Mass Movement‬ ‭GEOLOGY‬ ‭ASPECT‬ ‭Weathering‬ ‭Weathering‬ ‭Mass Movement‬ ‭Mass Movement‬ ‭ALTITUDE‬ ‭A reason of your choice:‬ ‭Weathering‬ ‭Weathering‬ ‭Mass Movement‬ ‭Mass Movement‬ ‭30‬ ‭Lesson 8: What Processes Carve Out Upland Landforms Such as V-shaped Valleys, Interlocking‬ ‭Spurs and Waterfalls?‬ ‭ s rivers begin high up in the mountains, water‬‭flows‬‭quickly downhill‬‭in the upper course,‬ A ‭resulting in‬‭vertical erosion‬‭(this is when the‬‭riverbed‬‭is eroded). This results in‬‭upland‬ ‭landforms‬‭(landforms found in the upper course of‬‭a river) such as Waterfalls, V-shaped Valleys‬ ‭and Interlocking Spurs.‬ ‭ river can flow over different rocks -‬ A ‭some are hard and some are softer. As‬ ‭water flows, it erodes the rocks.‬ ‭However, it erodes layers of softer rock‬ ‭more quickly and easily than the layers‬ ‭(or‬‭strata‬‭) of harder rock.‬ ‭ hat are Waterfalls?‬ W ‭A‬‭waterfall‬‭is when‬‭water flows steeply‬ ‭downward‬‭over a‬‭large‬‭drop in a‬ ‭riverbed.‬ ‭How are Waterfalls Formed?‬ ‭(1)‬ ‭There is a layer of hard rock‬ ‭over‬‭the soft rock at the‬ ‭riverbed. The water that flows‬ ‭over the hard rock, into the soft‬ ‭rock, will erode the soft rock‬ ‭through‬‭abrasion‬‭and‬‭hydraulic‬ ‭action‬‭. This is known as‬ ‭differential erosion‬‭.‬ ‭(2)‬ ‭At the base of a waterfall, a‬ ‭plunge pool‬‭is created by the‬ ‭flowing water and fluvial erosion‬ ‭(hydraulic action and abrasion).‬ ‭This deepens the waterfall.‬ ‭(3)‬ ‭Splashback‬‭from the falling‬ ‭water‬‭undercuts‬‭the hard rock‬ ‭further‬‭. Thus, the‬‭hard rock will be‬‭undercut‬‭until‬‭it creates an‬‭overhang‬‭.‬ ‭(4)‬ ‭Over time, the‬‭overhang will collapse‬ ‭into the river below because there is no‬ ‭support to hold it. It can break up into‬ ‭smaller rocks as it collapses, which can‬ ‭result in more abrasion,‬‭making the‬ ‭waterfall deeper.‬ ‭ he process of how a waterfall forms‬ T ‭continues, with soft rock eroding and hard rock‬ ‭collapsing. This results in the waterfall‬ ‭retreating upstream, carving a steep‬‭gorge‬ ‭into the landscape as it does.‬ ‭31‬ ‭Glossary‬ ‭‬ ‭Strata‬‭means layers‬ ‭‬ ‭Differential erosion‬‭is when softer rocks in the streambed‬‭wear away (or erode) faster‬ ‭than harder rocks.‬ ‭‬ ‭A‬‭plunge pool‬‭is a deep basin at the base of a waterfall‬‭with turbulent water.‬ ‭‬ ‭Splashback‬‭in a waterfall refers to the process where‬‭the water, after plunging down the‬ ‭waterfall, hits the plunge pool at the base and splashes back towards the rock face‬ ‭behind the waterfall.‬ ‭‬ ‭Undercut‬‭means to wear away (or cut) the part below‬‭or under something.‬ ‭‬ ‭An‬‭overhang‬‭is a part of something that extends (or‬‭hangs) over something else.‬ ‭‬ ‭A‬‭gorge‬‭is a narrow valley between hills or mountains,‬‭with almost-straight rocky walls‬ ‭and a stream running through it.‬ ‭Label the features of a waterfall you can observe in the pictures above.‬ ‭Draw and annotate the diagram below to show how a waterfall forms.‬ ‭32‬ ‭V-shaped Valleys‬ ‭ hat are V-shaped Valleys?‬ W ‭This is a valley whose typical cross section is shaped like‬ ‭a 'v'. These valleys have steep sloping sides and a‬ ‭narrow gap in between.‬ ‭How are V-shaped Valleys formed?‬ ‭(1)‬ ‭Rivers begin high up in the mountains so the‬ ‭water‬‭flows quickly downhill‬‭in the upper course,‬ ‭resulting in‬‭vertical erosion‬‭(this is when the‬ ‭riverbed is eroded).‬ ‭(2)‬ ‭The river cuts a deep notch down into the‬ ‭landscape using‬‭hydraulic action, abrasio‬‭n and‬ ‭corrosion / solution.‬ ‭(3)‬ ‭As the river erodes vertically, the sides of the‬ ‭valley are exposed to‬‭weathering‬‭which loosens‬ ‭the rocks.‬ ‭(4)‬ ‭Some of the weathered material will fall into the‬ ‭river through‬‭mass movement‬‭and this will‬ ‭steepen the sides of the valley. Over time, the channel becomes wider and deeper,‬ ‭creating a‬‭V-shaped valley‬‭.‬ ‭(a)‬ ‭The rocks which have fallen into the river assist the process of abrasion and this‬ ‭leads to further erosion. They can also be transported downstream.‬ ‭ nowledge-Check:‬ K ‭What are the differences between a gorge and a v-shaped valley?‬ ‭Interlocking Spurs‬ ‭ hat are Interlocking Spurs?‬ W ‭Interlocking spurs are ridges of land that jut out into a‬ ‭river valley. As the river winds around these harder rocks‬ ‭in the upper course, it creates a zigzag pattern, making‬ ‭the spurs appear to "interlock" from the sides of the‬ ‭valley.‬ ‭How are Interlocking Spurs formed?‬ ‭(1)‬ ‭Rivers begin high up in the mountains so the‬ ‭water flows quickly downhill in the upper course, resulting in‬‭vertical erosion‬‭(this is when‬ ‭the riverbed is eroded).‬ ‭33‬ ‭(2)‬ ‭As the river flows, it encounters areas of harder rock that are more resistant to erosion.‬ ‭The river can't easily erode these hard rock sections, so it has to‬‭wind around them‬‭.‬ ‭(3)‬ ‭The river bends around these hard rock obstacles,‬‭eroding the softer rock on either side‬‭.‬ ‭Over time,‬‭this creates a series of ridges that jut‬‭out into the valley:‬‭these are called‬‭spurs‬‭.‬ ‭(4)‬ ‭As the river continues to wind through the valley, it creates‬‭more spurs on alternating sides‬‭,‬ ‭which appear to‬‭"interlock" with each other‬‭when viewed‬‭from above or along the valley.‬ ‭These are called‬‭interlocking spurs‬‭.‬ ‭What features do you observe in the picture below? Label these!‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.2(c): How river landscapes change over the course of a river, with distinctive‬ ‭upland and lowland landforms, including the formation of valleys, interlocking spurs,‬ ‭waterfalls, meanders, oxbow lakes, floodplains and levees.‬ ‭‬ ‭Integrated Skills: Use GIS to map river systems.‬ ‭34‬ ‭Lesson 9: How Do Meanders, Oxbow Lakes, Floodplains and Levees Form in Lowland Areas?‬ ‭ s the river makes its way to the middle course, it gains more water and therefore more energy.‬ A ‭As a result,‬‭lateral erosion‬‭(erosion of the banks‬‭of the river) starts to widen the river.‬ ‭ owever,‬‭vertical erosion is still present in the‬‭middle course‬‭as the river is still flowing from higher‬ H ‭altitudes to the sea which is at a lower altitude.‬ ‭ t the same time, deposition of material also increases in the middle course, as the river loses‬ A ‭velocity‬‭(speed) at certain sections of the river:‬‭the river does not have the energy to carry its load‬ ‭so it deposits these.‬ ‭ combination of increased deposition and increased lateral erosion forms‬‭distinctive‬‭lowland‬ A ‭landforms‬‭(landforms found in the middle and lower‬‭course)‬‭such as meanders and oxbow lakes‬ ‭at the middle course‬‭and‬‭floodplains and levees in‬‭the lower course‬‭.‬ ‭Meanders‬ ‭ hat are Meanders?‬ W ‭A‬‭meander‬‭is a large, looping bend or curve in a‬ ‭river, typically found in the middle and lower‬ ‭courses. It is a‬‭lowland landform‬‭.‬ ‭How are Meanders Formed?‬ ‭(1)‬ ‭As the river flows over a relatively flat‬ ‭landscape, small bends or curves begin‬ ‭to form‬‭due to variations in the riverbed,‬ ‭obstacles, or differences in the river's‬ ‭velocity.‬ ‭(2)‬ ‭As a river goes around a bend, most of‬ ‭the water is pushed towards the outside.‬ ‭This causes‬‭increased speed‬‭and‬ ‭therefore‬‭increased‬‭lateral erosion‬ ‭(through hydraulic action and abrasion)‬ ‭on the outside bend‬‭. The‬‭undercutting‬ ‭of the river bank forms a‬‭river cliff‬‭.‬ ‭(3)‬ ‭Water on the‬‭inner bend is slower‬‭,‬ ‭causing the water to slow down and‬ ‭deposit‬‭material, creating a gentle slope‬ ‭of sand and shingle known as a‬‭slip-off‬ ‭slope‬‭.‬ ‭(4)‬ ‭Over time, the continuous erosion on‬ ‭the outer banks and deposition on the‬ ‭inner banks cause the bends to‬‭become‬ ‭more exaggerated‬‭, leading to the‬ ‭formation of distinct, snake-like curves‬ ‭known as‬‭meanders‬‭.‬ ‭Knowledge-Check: How is a Meander Different from Interlocking Spurs?‬ ‭36‬ ‭Oxbow Lakes‬ ‭ hat are Oxbow Lakes?‬ W ‭This is a U-shaped body of water (lake) formed from an‬ ‭abandoned bend in a river. It is a‬‭lowland landform‬‭.‬ ‭How are Oxbow Lakes Formed?‬ ‭(1)‬ ‭Due to‬‭erosion on the outside of a bend and‬ ‭deposition on the inside‬‭, the shape of a meander will‬ ‭change over a period of time.‬ ‭(2)‬ ‭Lateral erosion narrows the neck of the land within‬ ‭the meander‬‭and as the process continues, the‬ ‭meanders move closer together.‬ ‭(3)‬ ‭When there is a‬‭very high discharge (usually during‬ ‭a flood)‬‭, the river‬‭cuts across the neck,‬‭taking a‬‭new,‬ ‭straighter and shorter route.‬ ‭(4)‬ ‭Deposition‬‭will occur to‬‭cut off the original meander‬‭,‬ ‭leaving a U-shaped‬‭oxbow lake‬‭.‬ ‭ nowledge-Check‬‭: What features do you observe in the‬ K ‭picture below? Label these!‬ ‭37‬ ‭Floodplains‬ ‭ hat are Floodplains?‬ W ‭A floodplain is an area of land which is covered‬ ‭in water when a river bursts its banks. It is‬ ‭usually found in the lower course of a river (it is a‬ ‭lowland landform‬‭) and stretches from the banks‬ ‭of the river to the outer edges of the valley.‬ ‭ ow are Floodplains Formed?‬ H ‭Floodplains form due to both erosion and‬ ‭deposition.‬ ‭(1)‬ ‭In the‬‭lower course‬‭of a river,‬‭lateral‬ ‭erosion on the outer edge of a meander‬ ‭can wear down the valley slopes, making‬ ‭the valley‬‭wider and flatter,‬‭with no‬ ‭interlocking spurs.‬ ‭(2)‬ ‭During a flood‬‭, water overflows from its‬ ‭banks and‬‭infiltrates the soil‬‭surrounding‬ ‭the river on either side.‬ ‭(3)‬ ‭The water that infiltrates the soil,‬‭deposits‬‭a layer‬‭of sediment and material (‬‭rich in‬ ‭minerals‬‭).‬ ‭(4)‬ ‭Over time‬‭, the‬‭height of the floodplain increases‬‭as material is deposited‬‭on either side of‬ ‭the river and becomes‬‭a marshy land that is rich in‬‭vegetation‬‭.‬ ‭ hy are Floodplains Important?‬ W ‭Floodplains are often agricultural land, as the area is very fertile because it's made up of‬‭alluvium‬ ‭(deposited silt from a river flood).‬ ‭Use a highlighter to mark the floodplain of the‬‭Mississippi‬‭River (USA).‬ ‭38‬ ‭Levees‬ ‭ hat are Levees?‬ W ‭These are mounds of‬‭alluvium‬‭along the‬ ‭bank of a river, at the floodplain - so it is a‬ ‭landform usually found at the lower course‬ ‭of a river. It is a‬‭lowland landform‬‭.‬ ‭How are Levees Formed?‬ ‭(1)‬ ‭Sediment that has been eroded‬ ‭further upstream is transported‬ ‭downstream.‬‭When the river floods,‬ ‭the sediment spreads out across the‬ ‭floodplain‬‭.‬ ‭(2)‬ ‭When a flood occurs, the river loses‬ ‭energy.‬ ‭(3)‬ ‭The‬‭largest material is deposited first‬ ‭on the sides of the river banks and‬ ‭smaller material further away‬‭.‬ ‭(4)‬ ‭After many floods,‬‭the sediment builds up to increase‬‭the height of the river banks‬‭. This‬ ‭means that the channel can carry more water (a greater discharge) and flooding is less‬ ‭likely to occur in the future.‬ ‭What features do you observe in the picture below? Label these!‬ ‭39‬ ‭Lesson 10: Can You Read a Map?‬ ‭Recall Task:‬‭Match the contour lines with the shape‬‭of the hill.‬ ‭ ontour lines‬‭are lines on a map that‬ C ‭connect points of equal elevation (heights) in‬ ‭metres above sea level.‬‭They show the‬ ‭topography‬‭(the height and shape of the‬ ‭land).‬ ‭ ontour lines are drawn for certain elevations‬ C ‭(heights) only so that the map is not too‬ ‭crowded. These lines are evenly spaced‬ ‭apart.‬ ‭ ometimes not every contour line has a‬ S ‭number of metres written on it for the height of the land. If‬ ‭this is the case,‬‭you need to look at the height of‬‭the lines‬ ‭around it to work out what each line represents.‬ I‭n the picture on the right, the two missing heights would‬ ‭be 20m and 40m.‬ ‭What can contours tell you about the shape of the land?‬ ‭‬ I‭f the contours are close together, you’re looking at a steep‬ ‭slope.‬ ‭‬ ‭If the contours have wide spaces in between — you are‬ ‭looking at a gentle slope.‬ ‭‬ ‭If there are no contours at all– the land is flat.‬ ‭‬ ‭It also tells you where hills and valleys are located (see‬ ‭picture)‬ ‭42‬ ‭Excerpt of Key:‬ ‭Figure A: Map of the Lower course of River Kingsbridge‬ ‭Use Figure A to answer the questions below:‬ ‭(i) Which direction is the River Kingsbridge flowing?.........................................................................‬ ‭Questions continue on next page‬ ‭43‬ ‭ ow Do You Calculate Distances On a Map?‬ H ‭Most maps have a scale so that we can calculate distances on maps. This is given by the scale‬ ‭statement (eg: 1:50,000) and/or by showing a scale line (pictured below).‬ ‭ he scale statement shows how much bigger the real world is than the map. If the scale is‬ T ‭1:50,000 it means that every 1 cm on the map represents 50,000 cm in the real world.‬ ‭ he easiest way to work out a‬‭straight line distance‬‭on the map is to use the scale line and a‬ T ‭ruler:‬ ‭(1) Hold the ruler between two points on the map that you want to know the distance between.‬ I‭n this case the distance shown on the ruler between then two points in 4 cm‬ ‭(2) Bring the ruler down to the scale line and hold it against it.‬ I‭n this case the 4cm on the ruler represents 4km on the map. So the real life distance between‬ ‭the two places is 4km.‬ ‭(ii) What is the distance from A to B in kilometres?.............................................................................‬ ‭(iii) What is the distance from A to B in miles?....................................................................................‬ ‭Questions continue on next page‬ ‭44‬ ‭ hat if you need to measure a curved distance ?‬ W ‭(e.g. a river or road)‬ (‭ 1) Divide up the curved line (eg: road or river) into‬ ‭small straight sections.‬ ‭(2) Then, use a piece of paper and pivot the paper‬ ‭alongside the curved line, marking off straight‬ ‭sections on the paper’s edge.‬ ‭(3) When you have finished step (2) above, you do‬ ‭the same as before, and hold the whole distance up‬ ‭against the scale line.‬ ‭(iv) What is the distance of the river shown in Box C?.......................................................................‬ ‭How Can You Tell The Height Of the Land on a Map?‬ ‭You have to either:‬ ‭‬ ‭Use the contour lines:‬‭they have a number‬ ‭attached to them. This is the height in metres‬ ‭above sea level.‬ ‭For example, Point D on the figure on the right is‬ ‭at 200 metres above sea level and Point C is at‬ ‭130 metres above sea level.‬ ‭‬ ‭Use‬‭spot heights‬‭:‬‭these are exactly the same as‬ ‭they sound. They give height (in metres above sea level) for one particular spot on the‬ ‭map.‬ ‭For example, the highest point of the mountain in the figure above is labelled with a spot‬ ‭height of 325 metres above sea level.‬ ‭(v) What is the height of the following locations:‬ ‭(a)‬ ‭Rickham.....................................................‬‭110-130m‬ ‭(b)‬ ‭The Parking spot at Soar.....................................................‬‭13‬ ‭3‬ ‭ -Figure Grid References‬ 4 ‭A map often has grid squares over the top of it. These grid lines are to‬ ‭help you pinpoint a particular location. On most maps, each grid square‬ ‭represents 1km by 1km in real life.‬ ‭ o give the grid reference, use the coordinates in the‬‭bottom-left‬‭of the‬ T ‭square. The‬‭vertical numbers (x-axis) always come first; then the‬ ‭ orizontal numbers (y-axis).‬‭The grid reference for the‬ h ‭is therefore‬ ‭0113‬‭.‬ ‭ -Figure Grid References‬ 6 ‭Sometimes on a map we need to pinpoint a location within a 1 km‬ ‭square and need to be more precise. In this case we use 6 figure grid‬ ‭references.‬ ‭45‬ ‭ ook at the grid on the right. We could easily give the four figure grid reference for the square‬ L ‭with the orange and blue balls as 1201 using the method explained above.‬ ‭ o give a more exact 6 figure grid reference, you‬ T ‭must imagine that the grid square is divided into‬ ‭100 little squares:‬ ‭ e number the new imaginary squares from 0-9‬ W ‭going up and across the square. To give the 6‬ f‭igure grid reference for the blue ball‬ ‭, we‬ ‭insert numbers in between the 4-figure grid‬ ‭reference.‬ ‭So: 1201 would be 12‬‭1‬‭01‬‭1.‬ ‭The orange circle would be: 126017‬ ‭(vii) What is the Grid Reference for:‬ ‭(a)‬ ‭Snapes Manor?.....................................................‬ ‭(b)‬ ‭Public Telephone at East Portlemouth?.....................................................‬ ‭(viii) What do the following grid references show:‬ ‭(a)‬ ‭765356.....................................................‬ ‭(b)‬ ‭696391.....................................................‬ ‭46‬ ‭Practice Questions‬ ‭Grid squares represent 1 km by 1 km‬ ‭Figure X‬ ‭Figure Y‬ (‭ a) What is the grid reference of:‬ ‭(i) Cross Fell (Point A)? ……………………………………..‬ ‭(ii) High Force? ……………………………………..‬ ‭(iii) Cow Green Reservoir? ……………………………………..‬ (‭ b) What is the height above sea level of:‬ ‭(i) Cross Fell? ……………………………………..‬ ‭(ii) The Source of River Tees? ……………………………………..‬ ‭(c) Which direction is the River Tees flowing? ……………………………………..‬ (‭ d) What is the distance between‬ ‭(i) Cross Fell and the Source of River Tees? ……………………………………..‬ ‭(ii) Cross Fell and High Force? ……………………………………..‬ ‭Questions continue on next page‬ ‭(e) Describe the topography near the Source of River Tees using Figure Y.‬ ‭47‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭Skills: Can You Find River Landforms on a Map?‬ ‭48‬ ‭49‬ ‭50‬ ‭Figure B: Changes in Landscape Along a Long Profile‬ ‭Practice: Reading an OS Map to Identify Landforms on a Long Profile‬ ‭The following series of maps shows different sections of the River Tees in the UK.‬ ‭Complete the table below. You can use Figure B above to help you as well.‬ ‭ hich section of the river‬ W ‭is this?‬ ‭Upper course‬ ‭Middle course‬ ‭Lower course‬ ‭ tate three reasons for‬ S ‭your choice:‬ ‭(1)‬ ‭(2)‬ ‭(3)‬ ‭Figure C‬ ‭51‬ ‭ hich section of the river‬ W ‭is this?‬ ‭Upper course‬ ‭Middle course‬ ‭Lower course‬ ‭ tate three reasons for‬ S ‭your choice:‬ ‭(1)‬ ‭(2)‬ ‭(3)‬ ‭Figure D‬ ‭ hich section of the river‬ W ‭is this?‬ ‭Upper course‬ ‭Middle course‬ ‭Lower course‬ ‭ tate three reasons for‬ S ‭your choice:‬ ‭(1)‬ ‭(2)‬ ‭(3)‬ ‭Figure E‬ ‭52‬ ‭ hich section of the river‬ W ‭is this?‬ ‭Upper course‬ ‭Middle course‬ ‭Lower course‬ ‭ tate three reasons for‬ S ‭your choice:‬ ‭(1)‬ ‭(2)‬ ‭(3)‬ ‭Figure F‬ ‭ hich section of the river‬ W ‭is this?‬ ‭Upper course‬ ‭Middle course‬ ‭Lower course‬ ‭ tate three reasons for‬ S ‭your choice:‬ ‭(1)‬ ‭(2)‬ ‭(3)‬ ‭Figure G‬ ‭53‬ ‭Lesson 11: How Does a River Change Along its Course?‬ ‭Case Study: River Tees‬ ‭Figure A: Drainage Basin of the River Tees‬ ‭Figure B: High Force Waterfall‬ ‭ ecall Task:‬‭Complete row 1 and 2 in the table below.‬‭Figure A and B above and Figures C-G in‬ R ‭Lesson 10 will help you identify the river landforms.‬ ‭ pper course of River‬ M U ‭ iddle course of River‬ L ‭ ower course of River‬ ‭Tees‬ ‭Tees‬ ‭Tees‬ ‭1‬ ‭River Landforms‬ ‭2‬ ‭ ain river‬ M ‭processes‬ (‭ Hint: v-shaped‬ ‭valleys are because‬ ‭of vertical erosion,‬ ‭weathering and‬ ‭mass movement…)‬ ‭54‬ ‭3‬ ‭Channel width‬ ‭4‬ ‭Channel depth‬ ‭5‬ ‭Discharge‬ ‭6‬ ‭ elocity‬‭(speed‬ V ‭of water flowing)‬ ‭7‬ ‭Sediment size‬ ‭8‬ ‭Sediment shape‬ ‭9‬ ‭ radient‬ G ‭(steepness)‬ ‭10‬ ‭Land Use‬ ‭ he‬‭Bradshaw Model‬‭is a theoretical model that describes‬‭how a river's characteristics change‬ T ‭from its source to its mouth. Does the River Tees fit the model?‬ ‭Figure C: Bradshaw Model‬ ‭Take notes and label Figure C during the class discussion!‬ ‭ ll rivers have a long profile and cross profiles.‬‭Each river's long and cross profiles are unique but‬ A ‭they do have some characteristics in common.‬ ‭ ong Profile‬ L ‭The course of a river drawn from source to mouth is known as a‬‭long profile‬‭. It shows the‬ ‭changes in‬‭altitude‬‭(height above sea level)‬‭and‬‭gradient‬‭(the steepness) of a river.‬ ‭ he long profile is divided into three stages. The upper course, the middle course and the lower‬ T ‭course, each of which have distinctive characteristics.‬ ‭55‬ ‭Figure D: Long Profile of a River‬ ‭How does the altitude of the river change along its long profile?‬ ‭………………………………………………………………………………………………………………‬ ‭………………………………………………………………………………………………………………‬ ‭………………………………………………………………………………………………………………‬ ‭How does the gradient of the river change along its long profile?‬ ‭………………………………………………………………………………………………………………‬ ‭………………………………………………………………………………………………………………‬ ‭………………………………………………………………………………………………………………‬ ‭………………………………………………………………………………………………………………‬ ‭………………………………………………………………………………………………………………‬ ‭What factors affect the long profile of a river?‬ ‭56‬ ‭Choose any three factors from the debate and explain these in the table below:‬ ‭Factor‬ ‭Explanation‬ ‭Rank‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.2(b): How channel shape (width, depth), valley profile (long and cross profiles),‬ ‭gradient, velocity, discharge, and sediment size and shape change along the course of a‬ ‭named river.‬ ‭‬ ‭Integrated Skills: Use geology maps (paper or online) to link river long profiles to geology.‬ ‭‬ ‭Case Study: River Tees (UK)‬ ‭57‬ ‭Lesson 12: What Causes Shifts in a River's Cross Profile?‬ ‭Recall Activity:‬ ‭How does the rock type affect the long profile of the River Tees?‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭…………………………………………………………………………………………………………………..‬ ‭58‬ ‭Why does the cross profile of a river change from the upper course to the lower course?‬ ‭Note that the depth of the water increases from the upper to lower course.‬ ‭How would the long and cross profile of a river change if:‬ ‭ eforestation occurred‬ D ‭on the slopes of the hill‬ ‭and valley next to the‬ ‭river‬ ‭ griculture occurred on‬ A ‭the floodplains‬ ‭ eanders were‬ M ‭straightened near the‬ ‭mouth to create a port‬ ‭ dam and reservoir‬ A ‭were added at the upper‬ ‭course of a river‬ ‭59‬ ‭ kills: Drawing a Cross Profile‬ S ‭The‬‭cross profiles‬‭of a river are cross-sections from‬‭one bank to another.‬ ‭ an You Draw A Cross Profile of a River?‬ C ‭(1) Take a piece of paper and place it across the section you are studying. Mark each contour‬ ‭and the height of each contour.‬ ‭(2) On a graph, put a scale on the Y axis according to the height above sea level.‬ ‭(3) Place the piece of paper along the X axis, where each contour line is marked on the height.‬ ‭Join the lines together to create the shape of the valley.‬ ‭ igure A below shows a close-up of the Source of River Tees. Use the information in it to draw a‬ F ‭cross profile of the river.‬ ‭Figure A‬ ‭60‬ ‭ hat does the cross profile you drew above tell you about the river and its features at this‬ W ‭location?‬ ‭………………………………………………………………………………………………………………‬ ‭………………………………………………………………………………………………………………‬ ‭………………………………………………………………………………………………………………‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.2(b): How channel shape (width, depth), valley profile (long and cross profiles),‬ ‭gradient, velocity, discharge, and sediment size and shape change along the course of a‬ ‭named river.‬ ‭‬ ‭Integrated Skills: Use geology maps (paper or online) to link river long profiles to geology.‬ ‭‬ ‭Case Study:‬‭any one of -‬‭River Tay, Yangtze River,‬‭Nile River and Ebro River‬ ‭61‬ ‭Lesson 13: Who Has Access to Clean Water?‬ ‭ ater quality‬‭refers to the chemical, physical, and‬‭biological characteristics of water, which‬ W ‭determine its suitability for various uses like drinking, agriculture, and supporting ecosystems.‬ ‭ igh water quality‬‭means water is free from pollutants,‬‭safe for consumption, and capable of‬ H ‭sustaining healthy ecosystems. Contaminated water can cause health issues, harm wildlife, disrupt‬ ‭agriculture, and lead to costly water treatment.‬ ‭ hat Affects the Quality of Water?‬ W ‭The following human activities affect the quality of water. Categorise them into: (1) agricultural, (2)‬ ‭industrial and (3) domestic activities.‬ ‭ ntreated or partially treated‬ U I‭ndustries often discharge‬ ‭ oil erosion due to‬ S ‭sewage introduces pathogens‬ ‭chemicals and heavy metals‬ ‭deforestation introduces‬ ‭(bacteria, viruses, and‬ ‭(such as mercury, lead, and‬ ‭sediment into waterways. This‬ ‭parasites) and organic matter‬ ‭cadmium) into water bodies,‬ ‭can negatively affect‬ ‭into water systems.‬ ‭which are toxic to life.‬ ‭photosynthetic aquatic plants‬ ‭and habitats.‬ ‭ esticides and weedicides‬ P ‭ mall plastic particles come‬ S ‭ ivestock farms can contribute‬ L ‭leach into water sources‬ ‭from synthetic fibres, personal‬ ‭organic waste (manure) and‬ ‭through surface runoff,‬ ‭care products, and household‬ ‭pathogens to water sources,‬ ‭introducing toxins into water‬ ‭items. This introduces‬ ‭increasing bacteria and leading‬ ‭bodies.‬ ‭microplastics to water.‬ ‭to waterborne diseases.‬ ‭ xcess fertilisers containing‬ E ‭ ater used in industrial‬ W ‭ ertain industrial processes,‬ C ‭nitrogen and phosphorus can‬ ‭cooling is often released at‬ ‭like mining, can release acidic‬ ‭wash into nearby water bodies,‬ ‭higher temperatures, causing‬ ‭compounds (such as sulfuric‬ ‭promoting rapid algal growth.‬ ‭thermal pollution, which‬ ‭acid) into water, which lowers‬ ‭Algae deplete oxygen when‬ ‭affects temperature-sensitive‬ ‭pH levels and makes toxic‬ ‭they decompose, creating‬ ‭species.‬ ‭metals more soluble.‬ ‭"dead zones" where most‬ ‭aquatic life struggles to‬ ‭survive. This is known as‬ ‭eutrophication‬‭.‬ ‭What are some other ways that domestic use of water pollutes water bodies?‬ ‭What are the impacts of pollution above for:‬ ‭Humans‬ ‭Environment (Plants and Animals)‬ ‭65‬ ‭ ho Has Access to Clean Water?‬ W ‭Almost three-quarters of the world's population uses a safely managed water source, but why do‬ ‭some areas of the world have easier access to water than others?‬ ‭ hich regions of the‬ W ‭Reason:‬ ‭world have access to‬ ‭basic drinking water?‬ ‭ hich regions of the‬ W ‭Reason:‬ ‭world do not have‬ ‭access to safe water‬ ‭(through an improved‬ ‭water source)?‬ ‭ hich rivers in the‬ W ‭Reason:‬ ‭world are most‬ ‭polluted? Which ones‬ ‭are the least polluted?‬ ‭Glossary‬ ‭‬ ‭Basic Drinking Water is‬‭water from protected wells‬‭or springs in less than 30 minutes‬ ‭distance‬ ‭‬ ‭Improved water‬‭sources‬‭are those that have the‬‭potential‬‭to deliver safe water and‬ ‭include: piped water, boreholes or tubewells, protected dug wells, protected springs,‬ ‭rainwater, and packaged or delivered water.‬ ‭How does access to clean water differ between developing and developed countries?‬ ‭66‬ ‭How Can We Get Clean Water?‬ ‭ ollection‬‭of water is from rivers, dams/reservoirs,‬‭lakes, aquifers (especially in dry climates) and‬ C ‭wells.‬ ‭‬ ‭In developing economies and villages, untreated water is often collected in buckets from‬ ‭wells‬‭for homes. Buckets and plastic containers can‬‭further contaminate the water as they‬ ‭may be dirty, and open buckets of water can be contaminated by dust, insects and‬ ‭animals. A lot of time is also spent in collecting water.‬ ‭‬ ‭Water is also‬‭collected and delivered‬‭in‬‭plastic bottles‬‭filled at a‬‭source‬‭, such as a spring.‬ ‭This is a very expensive way to deliver water (cost of plastic containers, filling and‬ ‭transporting to the point of sale). However, it is used frequently by those who are worried‬ ‭about the quality of water treatment of piped water‬ ‭ ater that is collected may also undergo‬ W ‭treatment‬‭, which‬‭removes pollutants from the‬ ‭collected water. This occurs in a series of‬ ‭stages:‬ ‭1.‬ ‭Coagulation‬‭: Chemicals are added to‬ ‭the water so that small particles in the‬ ‭water stick together, forming‬‭larger‬ ‭particles called‬‭flocs‬‭. This makes it‬ ‭easier to remove these materials.‬ ‭2.‬ ‭Sedimentation‬‭: the water sits in large‬ ‭tanks where gravity helps the‬‭flocs‬ ‭settle to the bottom. This forms a‬ ‭sludge layer‬‭, which is removed. The‬ ‭remaining clear water moves to the next‬ ‭stage.‬ ‭3.‬ ‭Filtration‬‭: water is passed through filters (layers‬‭of sand and gravel or a screen) to remove‬ ‭very small particles that could not be removed through sedimentation.‬ ‭4.‬ ‭Disinfection‬‭: water is disinfected to kill remaining‬‭bacteria, viruses, and parasites using‬ ‭chlorine or UV light.‬ ‭5.‬ ‭Additional treatment: Aeration‬‭: exposing water to‬‭air (by‬ ‭using air bubbles in tanks). This helps to remove dissolved‬ ‭gases (eg: carbon dioxide) and excess minerals (eg: iron,‬ ‭manganese) by reacting with these elements. This also‬ ‭improves the water's oxygen content.‬ ‭Delivery of treated water:‬ ‭‬ ‭In developed economies and urban areas, water is‬ ‭delivered from treatment plants by‬‭pipes‬‭. However,‬‭the cost‬ ‭of installing and maintaining pipe networks is high, and if‬ ‭not maintained, the cost of leaks can be very high.‬ ‭‬ ‭In developing economies and / or villages, water can also‬ ‭be collected from a‬‭standpipe‬‭(see picture on right),‬‭which is a vertical pipe connected to a‬ ‭water supply and residents from around the area can collect water for themselves through‬ ‭this. It is used in areas without direct water connections to individual homes or buildings.‬ ‭Which section of the syllabus does this topic connect to?‬ ‭‬ ‭Section 1.3(b): Reasons for variations in water quality, including pollution (sewage,‬ ‭industrial waste, agriculture) and the storage and supply of clean water (dams and‬ ‭reservoirs, pipelines, treatment works).‬ ‭‬ ‭Integrated Skills: Use different maps (paper or online) to investigate the impact of human‬ ‭intervention.‬ ‭67‬ ‭Figures‬ ‭Figure A: Share of People in the World Without Access to Basic Drinking Water (2020)‬ ‭Figure B: People not using an improved water source (2022).‬ ‭Figure C: Municipal solid waste (MSW) leakage in rivers in 2020.‬ ‭68‬ ‭Lesson 15: Case Studies‬ ‭Questions on case studies for the IGCSE exam can be:‬ ‭‬ ‭4-mark questions on a situation happening in a developed or emerging / developing‬ ‭country.‬‭For these, you must be able to summarise‬‭what is happening about water supply,‬ ‭water demand, water quality, water storage or flood risk in two points (each of these should‬ ‭be explained for one more mark in the answer).‬ ‭‬ ‭8-mark questions‬‭- here, you will be given a new case‬‭study which you may not have learnt.‬ ‭You must be able to apply your knowledge to this new situation - in other words, when you‬ ‭get the question, think about: can anything in the case studies we learnt in class apply to this‬ ‭new case study?‬ ‭How to use the notes for case studies:‬ ‭‬ ‭Memorise TWO key facts for‬‭each‬‭case study. These‬‭must be specific to the case‬ ‭study‬‭(eg: (1) GERD is creating conflict over water‬‭in Sudan, Ethiopia and Egypt, (2) the‬ ‭reservoir Lake Mead is decreasing in size).‬ ‭‬ ‭Know the significance of each case study and the main impacts.‬‭You should be able to‬ ‭correctly explain the situation in each case study to a friend.‬ ‭‬ ‭You do NOT need to remember every single detail / fact / statistic provided on these‬ ‭notes. Th

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