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(a) (i) The sphere of influence is the area served by a settlement, shop, or service.
(ii) Factors include:
- The population size of the settlement.
- The range and order of goods/services provided.
- The quality of accessibility/transport links.
- The degree of competition from other neighboring settlements.
(iii) Frequency of use: Services used daily (e.g., bakeries) need a small threshold population because people purchase products constantly. Services used rarely (e.g., furniture shops) need a much larger threshold population to ensure enough customers over a given period.
Cost: Expensive services require a higher threshold population to make a profit because fewer transactions occur, whereas cheap goods can rely on small populations.
(iv) Low-order services (e.g., newsagents, grocery stores) offer convenience goods that are cheap, bought frequently, and have a short range/threshold, meaning they can survive in small villages as well as large cities. High-order services (e.g., luxury car dealerships, specialist hospitals) provide comparison goods that are expensive, bought rarely, and have a huge threshold population and range, which is only supported by the massive, diverse population of a major city.

(b) (i) In the zone of transition (inner city), housing is older (often Victorian/industrial), higher density (terraced housing, high-rise flats), and lacks private open green spaces. In contrast, the suburbs feature modern, lower-density housing (detached/semi-detached houses), large private gardens, and tree-lined streets with nearby parks.
(ii) Challenges in rapidly growing LEDC cities include:
- Formation of squatter settlements/slums with poorly built, hazardous housing.
- Lack of clean piped water, proper sewage systems, and sanitation, causing water-borne diseases.
- High rates of unemployment or underemployment, pushing people into dangerous or poorly paid informal jobs.
- Severe traffic congestion and air/water pollution due to overburdened municipal infrastructure.
- Overcrowded schools, hospitals, and high crime rates due to inadequate municipal policing and funding.

(c) Case Study: London, UK (Traffic Congestion)
- Strategy 1: Congestion Charge. Introduced in central London, charging vehicles driving into the central zone. This directly reduced private vehicle volume and encouraged public transport usage.
- Strategy 2: Cycle Superhighways and Santander Cycles. Dedicated cycle lanes protected from traffic lanes were created, along with public bike-sharing schemes, facilitating zero-emission commuting.
- Strategy 3: Investment in Public Transport. Projects like Crossrail (the Elizabeth Line) and expansions of the London Underground have increased passenger capacity, reducing reliance on private cars.

(a) (i) 1 mark for clear definition:
- Area served by a settlement / shop / service.

(ii) 1 mark per valid factor (max 2):
- Population size of the settlement.
- Range / order of goods and services.
- Level of transport links / accessibility.
- Level of competition from nearby settlements.

(iii) 3 marks total:
- 1 mark for linking high frequency of use to a low threshold population (or vice versa).
- 1 mark for linking high cost to a high threshold population (or vice versa).
- 1 mark for clear reasoning / exemplification.

(iv) 4 marks total:
- 1 mark for identifying low-order services as having small range/threshold/convenience.
- 1 mark for explaining why villages can support low-order services.
- 1 mark for identifying high-order services as having large range/threshold/comparison.
- 1 mark for explaining why only cities can support high-order services.

(b) (i) 3 marks total (must compare/contrast both zones to get full marks):
- Max 2 marks if only describing one zone.
- Points: high density vs low density; terraced/flats vs detached/semi-detached; lack of green space vs private gardens; older vs modern housing.

(ii) 5 marks total (1 mark per distinct challenge explained):
- Squatter settlements / poor building structures [1]
- Inadequate sanitation / lack of clean water [1]
- High unemployment / growth of informal sector [1]
- Traffic congestion / air pollution [1]
- High crime / strain on services (schools/hospitals) [1]

(c) 7 marks total (Case Study):
- Level 1 (1-3 marks): Simple, generic statements describing a problem or strategy without specific local detail.
- Level 2 (4-6 marks): Explains specific strategies for a named urban area, explaining *how* they work.
- Level 3 (7 marks): Detailed, comprehensive explanation with specific names of strategies and place-specific details for the chosen city.

(a) (i) Barometer (or Aneroid Barometer).
(ii) Read the maximum temperature at the base of the index on the maximum side. Read the minimum temperature at the base of the index on the minimum side. Subtract the minimum temperature from the maximum temperature to find the diurnal temperature range.
(iii) Read the air temperature on the dry-bulb thermometer. Read the temperature on the wet-bulb thermometer (which is cooled by evaporation). Subtract the wet-bulb temperature from the dry-bulb temperature to find the wet-bulb depression. Use a relative humidity conversion table to find where the dry-bulb value and wet-bulb depression intersect.
(iv) It must be placed in an open area, away from tall trees and buildings (to avoid shade and artificial wind blockages). It should be sited over grass (not concrete/tarmac, which absorb and radiate heat). It must be elevated 1.25 meters above the ground (to prevent ground radiation from affecting the air temperature readings). It must be painted white (to reflect direct sunlight).

(b) (i) Features: Fluffy, cotton-wool appearance, white at the top with a dark, flat base. Formation: Convection currents occur when the sun heats the ground, heating the air above it. The warm air rises, cools at the dry adiabatic lapse rate, reaches dew point, and condenses into cloud droplets.
(ii) High temperatures: High solar angle means concentrated insolation; clear skies allow maximum incoming solar radiation to reach the desert surface without cloud reflection. Low rainfall: Located at 20° to 30° north and south of the equator, in the subtropical high-pressure belt where air is descending, warming, and drying, preventing condensation. Prevailing trade winds are blowing from land to sea (offshore) and contain little moisture.

(c) Case Study: Cyclone Nargis in Myanmar (2008)
- Impact 1: Severe flooding of the Irrawaddy Delta caused by a 3.5-meter storm surge, which swept away coastal villages and drowned livestock.
- Impact 2: Over 138,000 deaths and widespread destruction of infrastructure, including hospitals, roads, and communication lines, which delayed emergency aid.
- Impact 3: Loss of agricultural land. The storm surge salinized fertile rice paddies, destroying crops and causing long-term food insecurity and economic hardship for local farmers.

(a) (i) 1 mark for Barometer / Aneroid Barometer.

(ii) 2 marks:
- 1 mark for identifying that the maximum and minimum readings are taken from the bottom of the metal indexes.
- 1 mark for explaining that the minimum temperature is subtracted from the maximum temperature.

(iii) 3 marks:
- 1 mark for recording dry-bulb and wet-bulb temperatures.
- 1 mark for calculating the wet-bulb depression (difference between the two).
- 1 mark for using relative humidity tables / chart.

(iv) 4 marks (1 mark per site condition explained, max 4):
- Sited on grass / natural surface (avoids concrete radiation) [1]
- Open space / away from buildings/trees (prevents shading/sheltering) [1]
- Standard height / 1.25-1.5m above ground (avoids ground heat transfer) [1]
- Painted white (reflects solar radiation) [1]
- Louvered / slatted sides (allows free flow of air) [1]

(b) (i) 3 marks:
- 1 mark for features (fluffy/cotton-wool/flat base).
- 1 mark for rising air/convection currents due to ground heating.
- 1 mark for air cooling, reaching dew point, and condensing.

(ii) 5 marks (max 3 on temperatures, max 3 on rainfall):
- Descending air in subtropical high-pressure belts [1]
- Prevailing winds are offshore/continental (dry) [1]
- High solar angle / concentrated solar energy [1]
- Clear skies / absence of clouds allows rapid daytime heating [1]
- Cold ocean currents nearby cool the air and reduce moisture capacity [1]

(c) 7 marks total (Case Study):
- Level 1 (1-3 marks): General list of impacts of drought/tropical storm (deaths, loss of homes, food shortages).
- Level 2 (4-6 marks): Detailed descriptions of specific primary and secondary impacts in a named location.
- Level 3 (7 marks): Comprehensive, well-explained impacts with specific locational facts and figures for the named area.

(a) (i) The movement of water up the beach after a wave breaks.
(ii) Differences:
- Constructive waves have a stronger swash than backwash, whereas destructive waves have a stronger backwash than swash.
- Constructive waves have a lower wave height and frequency, whereas destructive waves have a higher wave height and frequency.
(iii) Hydraulic action: Waves crash against the cliff, trapping air in cracks. The air is compressed, and as the wave retreats, the pressure is suddenly released, causing the rock to shatter.
Abrasion: Waves fling rocks, sand, and pebbles against the base of the cliff, chipping away and wearing down the rock surface like sandpaper.
(iv) Waves approach the shore at an oblique angle, driven by the prevailing wind. The swash carries sediment up the beach at this same angle. The backwash then drags sediment straight back down the beach at a right angle (90 degrees) due to gravity. This continuous zig-zag movement transports material along the coast.

(b) (i) Longshore drift moves sediment along the coast. Where there is a change in the shape of the coastline (e.g., at an estuary or headland), the sediment is deposited in the sheltered, shallow water. Over time, deposition builds up a ridge of sand and shingle that projects out into the sea. Winds or secondary waves may curve the end of the spit, forming a hook.
(ii) Formation: Coral reefs are built by millions of tiny polyps that extract calcium carbonate from seawater to build protective skeletons. When they die, new polyps grow on top of the old skeletons, building up the reef.
Conditions required:
- Warm sea temperatures between 18°C and 30°C.
- Shallow water (less than 60m) so sunlight can reach zooxanthellae (algae) for photosynthesis.
- Clean, clear, sediment-free water to prevent smothering.
- Saline, well-oxygenated water with strong waves to bring nutrients.

(c) Case Study: Holderness Coast, Yorkshire, UK
- Opportunities: Tourism in seaside resorts like Hornsea and Bridlington, where sand beaches support local shops and guest houses. Gas terminals at Easington process a significant proportion of the UK's North Sea gas, providing energy and employment.
- Hazards: Severe coastal erosion (soft boulder clay cliffs erode at up to 2 meters per year). This has caused homes to fall into the sea at villages like Skipsea, dropping property values and causing psychological distress to residents. Coastal roads are also destroyed, isolating communities.

(a) (i) 1 mark for defining swash (movement of water up the beach).

(ii) 2 marks for stating two differences (1 mark per distinct comparative point):
- Constructive waves have strong swash/weak backwash, destructive have weak swash/strong backwash.
- Constructive waves are low/gentle, destructive waves are high/steep.
- Constructive waves deposit, destructive waves erode.
- Constructive waves have low frequency, destructive waves have high frequency.

(iii) 3 marks:
- 1.5 marks for explaining hydraulic action (trapped air, compression, sudden release/shattering).
- 1.5 marks for explaining abrasion (waves throwing sediment/rocks against the cliff base).

(iv) 4 marks:
- Prevailing wind blows waves at an angle to the coast [1]
- Swash carries material up the beach at an angle [1]
- Backwash carries material straight down due to gravity [1]
- Repetition of this process leads to a zig-zag movement along the coast [1]

(b) (i) 3 marks:
- Longshore drift carries sediment past a change in coast shape / river mouth [1]
- Sediment is deposited in the slack, shallow water [1]
- Ridge grows outward and curves at the end due to change in wind direction / currents [1]

(ii) 5 marks (max 2 on polyp formation, max 4 on environmental conditions):
- Polyps build calcium carbonate skeletons [1]
- Warm water temperatures (18°C to 30°C) [1]
- Shallow water / less than 60m depth (sunlight) [1]
- Clear, sediment-free water [1]
- Saline water / high oxygen levels [1]

(c) 7 marks total (Case Study):
- Level 1 (1-3 marks): Simple description of opportunities and hazards in general coastal areas.
- Level 2 (4-6 marks): Explains specific opportunities and hazards for a named coastal area.
- Level 3 (7 marks): Detailed, balanced case study with specific locational details and clear explanations of both opportunities and hazards.

(a) (i) The point on the Earth's surface directly above the focus of an earthquake.
(ii) The focus is the exact point underground where the earthquake originates (the fracture point along the fault line). The epicentre is the point on the ground surface directly above it, where the strongest seismic shockwaves are first felt.
(iii) Convection currents in the mantle pull two plates toward each other. The denser, heavier oceanic plate is forced downward beneath the lighter continental plate in a process called subduction, moving into the asthenosphere where it melts due to intense friction and heat.
(iv) At conservative boundaries, two plates slide horizontally past one another, either in opposite directions or in the same direction at different speeds. The edges of the plates are rough and jagged, causing them to catch and become locked together by friction. As plates continue to try to move, tension and pressure build up in the rocks. Eventually, the strain exceeds the strength of the rock, causing it to suddenly fracture and slip, releasing accumulated potential energy as seismic waves.

(b) (i) Hazards:
- Pyroclastic flows: Superheated, fast-moving clouds of toxic gases, ash, and rock fragments that incinerate everything in their path.
- Ash fall: Fine volcanic ash that covers landscapes, collapses building roofs, ruins crops, and disrupts aviation.
- Lahars: Mudflows formed when volcanic ash mixes with melted snow/glaciers or heavy rain, rushing down river valleys.
(ii) Reduction through:
- Preparation: Regular earthquake drills in schools and offices to educate the public; disaster response kits; mapping high-risk seismic zones to avoid building there; installing early-warning warning sirens.
- Engineering: Constructing earthquake-resistant buildings using shock absorbers/base isolators at the foundations, cross-bracing steel frames, and using reinforced concrete. Installing flexible utility gas and water pipes to prevent fires and water supply failures.

(c) Case Study: Tohoku Earthquake, Japan (2011)
- Causes: Occoured at a convergent (destructive) plate boundary. The Pacific Plate subducted beneath the Eurasian Plate (North American subplate). Friction caused the plates to lock, building up massive elastic tension. On March 11, the plate ruptured, releasing a magnitude 9.0 earthquake and displacing a huge volume of water above the fault line.
- Effects: The earthquake caused building collapse and fires, but the resulting tsunami caused the vast majority of deaths (nearly 16,000 people drowned). The tsunami flooded the Fukushima Daiichi nuclear power plant, causing a cooling system failure, nuclear meltdowns, and radiation leaks, forcing over 150,000 people to evacuate their homes.

(a) (i) 1 mark for: Point on surface directly above the focus.

(ii) 2 marks:
- 1 mark for describing the focus (point underground where slip/fracture begins).
- 1 mark for describing the epicentre (point on the surface with highest initial wave intensity).

(iii) 3 marks:
- 1 mark for plates moving towards each other due to convection currents.
- 1 mark for subduction of the denser oceanic plate.
- 1 mark for melting of plate in the subduction zone / trench formation.

(iv) 4 marks:
- Plates slide past each other (opposite/same direction) [1]
- Friction causes the plates to lock/stick together [1]
- Stress/tension builds up in the rocks [1]
- Rock suddenly fractures, releasing energy/seismic waves [1]

(b) (i) 3 marks (1 mark per distinct hazard described):
- Pyroclastic flows (hot, fast cloud of ash/gas) [1]
- Ash falls (suffocation, roof collapse) [1]
- Lahars (mudflows of volcanic ash and water) [1]
- Toxic gas emissions (sulfur dioxide/CO2) [1]

(ii) 5 marks (max 3 on preparation, max 3 on engineering):
- Regular earthquake drills / education [1]
- Base isolators / rubber foundations in buildings [1]
- Cross-bracing / steel frames to absorb shock [1]
- Flexible gas/water mains to prevent secondary fires [1]
- Seismic mapping / zoning laws [1]
- Early warning systems [1]

(c) 7 marks total (Case Study):
- Level 1 (1-3 marks): Simple descriptions of causes or effects with general/unspecific tectonic statements.
- Level 2 (4-6 marks): Explains specific tectonic plate names/movements and details of both primary and secondary impacts.
- Level 3 (7 marks): Comprehensive case study with precise tectonic details (e.g., plates involved, Richter scale) and quantified impacts (death toll, cost, nuclear meltdown detail).

(a) (i) Mass tourism is tourism on a large scale, involving huge numbers of people visiting the same resort or destination at the same time.
(ii) Reasons:
- Growth in global disposable incomes, allowing more people to afford travel.
- Growth of budget airlines and cheaper flights, making air travel accessible.
- More paid annual leave and shorter working weeks.
- Easier booking systems via the internet and online travel agencies.
(iii) Benefits:
- Creates direct employment in hotels, restaurants, and as tour guides.
- Indirect employment through construction and local agricultural suppliers (multiplier effect).
- Tourism generates foreign exchange currency for the country.
- Tax revenues from tourism allow the government to improve infrastructure (roads, clean water, hospitals).
(iv) Environmental impacts:
- Clearance of natural habitats (e.g., clearing mangroves or forests) to build hotels.
- Water pollution from untreated sewage discharged into the sea, damaging coral reefs.
- High carbon emissions and air pollution from aircraft and tourist vehicles.
- Depletion of local groundwater reserves due to high consumption by hotels (golf courses, laundry, pools).

(b) (i) The Butler Model shows the evolution of a resort through stages:
- Exploration & Involvement: Very few tourists visit; basic local amenities are developed.
- Development & Consolidation: Mass tourism occurs with foreign investment, major hotel construction, and tourism becomes the dominant economic sector.
- Stagnation: Carrying capacity is reached; the resort becomes crowded, run-down, and starts losing its appeal.
- Decline or Rejuvenation: The resort either loses tourists to competitors (decline) or reinvests in new attractions/upgrades to attract visitors again (rejuvenation).
(ii) Sustainable management strategies:
- Enforce daily limits or quotas on tourist numbers (carrying capacity) to prevent overcrowding in fragile areas.
- Promote ecotourism where visitors stay in low-impact eco-lodges made of local renewable materials.
- Use renewable energy sources (solar/wind) and water recycling systems in hotels.
- Ensure a percentage of resort entrance fees goes directly to local wildlife conservation and community development.
- Ban plastic usage on beaches and create marine sanctuaries.

(c) Case Study: Maasai Mara, Kenya
- Development: Developed through safari-based tourism focusing on wildlife viewings (the Big Five) and cultural visits to Maasai villages. Luxury lodges and campsite networks have been built.
- Advantages: Created jobs for the local Maasai people as rangers, drivers, and hotel staff. Income is generated by selling handmade traditional crafts. Some tourism revenue is used to build local schools and health clinics.
- Disadvantages: Land has been taken from the Maasai, restricting their nomadic cattle grazing. Cultural dilution occurs as traditional dances are performed as commercial spectacles. High inflation of local food prices makes basic goods expensive for locals.

(a) (i) 1 mark for defining mass tourism (large scale / high volumes of tourists at one destination).

(ii) 2 marks (1 mark per distinct reason for growth):
- Increased disposable income.
- Lower transport costs / budget airlines.
- More leisure time / holiday entitlement.
- Internet / online booking convenience.

(iii) 3 marks (must focus on economic benefits):
- Direct jobs (hotels/guides) [1]
- Multiplier effect / indirect jobs (farmers, builders) [1]
- Infrastructure development funded by tax [1]
- Foreign currency earnings [1]

(iv) 4 marks (1 mark per distinct environmental impact described):
- Habitat destruction / deforestation [1]
- Sewage pollution in seas / damage to marine life [1]
- Air pollution / carbon footprint from flights [1]
- Water table depletion (hotel consumption) [1]

(b) (i) 3 marks:
- 1 mark for explaining the general concept of the model (stages of growth over time).
- 1 mark for naming/describing early stages (exploration/involvement/development).
- 1 mark for naming/describing late stages (stagnation/decline/rejuvenation).

(ii) 5 marks (1 mark per well-explained sustainable strategy):
- Restricting visitor numbers (carrying capacity) [1]
- Employing local staff and paying fair wages [1]
- Using eco-lodges / renewable energy [1]
- Directing tourism fees to local nature conservation [1]
- Restricting vehicle movements to protect soil/wildlife [1]

(c) 7 marks total (Case Study):
- Level 1 (1-3 marks): Simple statements explaining general development, advantages, or disadvantages of tourism.
- Level 2 (4-6 marks): Explains specific development factors, and both advantages and disadvantages for the local people in a named area.
- Level 3 (7 marks): Detailed and balanced case study with specific locational details, clear advantages, and disadvantages for the named community.

(a) (i) Secondary industry is the sector of the economy that processes raw materials into finished or semi-finished goods (manufacturing).
(ii) Inputs include: Raw materials, labor (workers), capital (investment), energy (electricity), and land.
(iii) Weight-losing (bulk-reducing) industries process heavy, bulky raw materials into lighter products (e.g., steel production), so factories locate near raw materials to minimize expensive transport costs.
Weight-gaining (bulk-gaining) industries produce items that are heavier or bulkier than the raw inputs (e.g., soft drink bottling), so they locate close to the market. Perishable products (e.g., bakeries) must also locate near the market to ensure freshness.
(iv) Government policies: Governments can set up enterprise zones with tax holidays, subsidies, and relaxed planning permissions to attract high-tech companies.
Transport networks: High-tech industries depend on rapid, high-quality transport networks like motorways and proximity to international airports to ship valuable, lightweight components quickly and to allow skilled workers to commute easily.

(b) (i) In an LEDC, a high percentage of the workforce is employed in the primary sector (agriculture/mining) due to low mechanization, and the tertiary sector is relatively small. In contrast, an MEDC has a very small primary sector due to high mechanization, a declining secondary sector (due to outsourcing), and a dominant tertiary sector (services, finance, and technology).
(ii) Environmental impacts:
- Air pollution: Factories release greenhouse gases (carbon dioxide) and sulfur dioxide, contributing to global warming and acid rain.
- Water pollution: Chemical effluents and heavy metals dumped into rivers/lakes destroy aquatic ecosystems.
- Solid waste: Toxic sludge and slag heaps take up land space and leak chemicals into the soil.
- Noise/light pollution: Industrial operations disturb local communities and wildlife patterns.
- Resource depletion: Heavy consumption of fossil fuels and raw mineral resources.

(c) Case Study: Toyota Manufacturing Plant, Burnaston, Derby, UK
- Factor 1: Excellent Transport Links. Located at the junction of the A50 and A38 dual carriageways, providing rapid road links to the M1 motorway and international airports, allowing components to arrive 'Just-in-Time' and finished cars to be easily exported.
- Factor 2: Large, Skilled Labor Pool. Derby has a strong traditional engineering heritage (e.g., Rolls-Royce), meaning there is an abundant supply of skilled mechanical and electrical engineers nearby.
- Factor 3: Flat, Greenfield Land. The plant was built on 110 hectares of flat, cheap, open farmland, which allowed for a large single-story assembly line layout and leaves space for future expansion.

(a) (i) 1 mark for defining secondary industry (manufacturing / processing raw materials into finished goods).

(ii) 2 marks (1 mark per correct input, max 2):
- Raw materials.
- Labor.
- Capital / finance.
- Energy / electricity.
- Land.

(iii) 3 marks:
- 1 mark for explaining weight-losing industries locating near raw materials.
- 1 mark for explaining weight-gaining / perishable industries locating near markets.
- 1 mark for exemplification / comparative transport cost reasoning.

(iv) 4 marks (2 marks for government role, 2 marks for transport role):
- Government: Tax incentives/subsidies [1] and enterprise zones/planning freedom [1].
- Transport: Motorways/roads for quick component movement [1] and airports for international travel/high-value freight [1].

(b) (i) 3 marks total (must compare LEDC and MEDC for full marks):
- LEDC has high primary, low/medium secondary, lower tertiary [1].
- MEDC has very low primary, declining secondary, very high tertiary [1].
- 1 mark for explaining comparative reasons (e.g., mechanization, outsourcing, development levels).

(ii) 5 marks (1 mark per distinct environmental impact explained):
- Gas emissions causing acid rain / global warming [1]
- Untreated liquid waste / chemicals polluting water bodies [1]
- Toxic solid waste dumping / soil contamination [1]
- High electricity consumption causing fossil fuel depletion [1]
- Visual / noise pollution impacting local fauna [1]

(c) 7 marks total (Case Study):
- Level 1 (1-3 marks): Simple description of general industrial location factors (e.g., space, workers, roads) without linking specifically to a named location.
- Level 2 (4-6 marks): Explains specific physical and human factors that attracted a named factory/industrial zone to its location.
- Level 3 (7 marks): Detailed, comprehensive case study of a named factory or zone (e.g., Toyota at Burnaston or Silicon Valley) with precise facts, figures, and road/region names, explaining *how* multiple factors influenced the choice.

(a)(i) The map symbol at 412783 represents a Picnic site. (a)(ii) The road running through 430750 is an A-class road or Primary Route. (a)(iii) The symbol at 426765 represents a Place of worship with a spire. (a)(iv) The triangulation station at 448792 shows a height of 142 metres. (b)(i) The measured distance on the map is 10.4 cm, which at a scale of \(1:25\ 000\) converts to 2600 metres (acceptable range 2500m to 2700m). (b)(ii) The direction from the church to the post office is East-South-East (ESE) and the bearing is 112 degrees (allow 110 to 114 degrees). (c) Relief: The northern and north-western parts feature steep slopes rising from 50m to over 200m. The southern part is flat valley floor (below 50m). Drainage: A main river flows from north-west to south-east across the square, with small tributary streams flowing down the steeper slopes. (d) Settlement patterns: Nucleated around the historic center of Glenford (grid square 4277); Linear along the A45 highway in the south; Dispersed with isolated farmsteads in the upland regions of the north-west; Avoidance of steep slope areas. (e) Location factors: 1. Flat land in grid square 4475 (indicated by absent or widely spaced contours) which minimizes site preparation and construction costs. 2. Transport access as it is situated adjacent to the railway line and primary road network, facilitating easy distribution of goods.

Total: 20 marks. (a)(i) 1 mark for Picnic site. (a)(ii) 1 mark for A-class road / primary route. (a)(iii) 1 mark for Place of worship with spire. (a)(iv) 1 mark for 142 metres. (b)(i) 2 marks for 2600m (allow 2500m to 2700m). 1 mark if distance is correct in cm (10.4 cm) but conversion to metres is incorrect. (b)(ii) 1 mark for ESE / East-South-East (allow East or South-East); 1 mark for 112 degrees (allow 110 to 114 degrees). (c) Relief and drainage: Max 4 marks (max 3 on relief or drainage alone). Relief points: Steep slopes in north/north-west (1 mark); flat valley floor in south (1 mark); height range 50m to over 200m (1 mark). Drainage points: Main river flows NW to SE (1 mark); tributary streams present (1 mark). (d) Settlement pattern: Max 4 marks. Nucleated around center / grid square 4277 (1 mark); Linear along road / A45 (1 mark); Dispersed/isolated buildings in upland/north-west (1 mark); Absence of settlement on steep slopes / high ground (1 mark). (e) Location of industrial area: 4 marks (2 marks per reason explained). 1 mark for identifying factor, 1 mark for explaining its benefit. e.g., Flat land (1 mark) makes building easier/cheaper (1 mark); Transport link/railway/road (1 mark) for importing raw materials / exporting products (1 mark); Near river (1 mark) for water supply/cooling (1 mark); Edge of town / away from housing (1 mark) to prevent noise/air pollution affecting residents (1 mark).

(a) Grid reference 452814 corresponds to a place of worship with a tower, indicated by the square symbol with a cross.
(b) The post office in Low Wood is located at 463821.
(c) The map distance is 15.2 cm. At a scale of 1:25000, 1 cm represents 0.25 km. Therefore, \(15.2 \times 0.25 = 3.8\text{ km}\).
(d) The settlement pattern is mixed: there is clear linear development along the B4012 road corridor, nucleated housing around the central crossroads, and isolated/dispersed farm dwellings in the northern agricultural areas.
(e) The map symbol 'PO' represents a Post Office, which is a key service in the Highfield settlement.

(a) 1 mark for identifying place of worship with tower / church with tower. Reject: place of worship with spire.
(b) 1 mark for 6-figure grid reference 463821. Accept tolerance: eastings 462 to 464, northings 820 to 822.
(c) 2 marks total: 1 mark for correct map measurement (14.8 to 15.6 cm), 1 mark for accurate conversion to kilometers (3.7 km to 3.9 km).
(d) 3 marks total: 1 mark for identifying linear pattern (along road), 1 mark for identifying nucleated pattern (at junction), 1 mark for identifying dispersed/scattered pattern in north.
(e) 1 mark for any valid service identified from map (e.g., Post Office / PO, Public House / PH, Hospital).

(a) Grid reference 124932 points to a long finger of sand extending into the estuary, which is a spit.
(b) The direction is West to East. This is proven by the buildup of sediment on the western side of the groynes and the eastward elongation of the spit at the mouth of the bay.
(c) Gradient is calculated as \(\text{Vertical rise (or drop)} \div \text{Horizontal distance}\). Therefore, \(2.5 \div 40 = 0.0625\), which is 1 in 16 or 6.25%.
(d) Coastal management is shown by the presence of groynes perpendicular to the shore to retain sand, rip-rap armor at the base of the cliffs to protect tourist structures, and protective fencing around sand dunes to prevent trampling.

(a) 1 mark for 'spit'. Reject: beach, bar.
(b) 2 marks total: 1 mark for direction (West to East or Eastwards), 1 mark for valid reason (e.g., spit extends east, sand traps on west side of groynes).
(c) 2 marks total: 1 mark for correct setup / division expression (\(2.5 \div 40\)), 1 mark for correct simplified gradient answer (1:16, 6.25%, or 0.0625).
(d) 3 marks total: 1 mark per valid management technique linked to map evidence (groynes to trap sediment, rip-rap/sea wall protecting development at 131935, fencing/restricted zones to conserve dunes).

(a) The highest point on the line graph is in July at a temperature of \(24^\circ\text{C}\).
(b) The maximum temperature is \(24^\circ\text{C}\) (July) and the minimum is \(8^\circ\text{C}\) (January). The range is \(24^\circ\text{C} - 8^\circ\text{C} = 16^\circ\text{C}\).
(c) The three wettest months are October (120 mm), November (140 mm), and December (130 mm). Total: \(120 + 140 + 130 = 390\text{ mm}\).
(d) Fig. 2 displays a cup anemometer. It measures wind speed. For accurate readings, it must be mounted high up (usually 10 meters) on a pole in an open space so that nearby buildings or trees do not block the wind.

(a) 1 mark for both correct month (July) and temperature value (24°C, accept 23.5°C to 24.5°C).
(b) 2 marks total: 1 mark for identifying correct max (24°C) and min (8°C) temperatures, 1 mark for correct calculation of 16°C (accept 15°C to 17°C).
(c) 2 marks total: 1 mark for identifying three wettest months and their values (Oct: 120, Nov: 140, Dec: 130), 1 mark for correct sum (390 mm, accept 380 to 400 mm).
(d) 3 marks total: 1 mark for naming Cup Anemometer, 1 mark for stating it measures wind speed (or velocity), 1 mark for placement reason (open space / high mast / away from obstacles).

(a) The main access gate is positioned precisely at grid reference 583192.
(b) Looking at the transport symbols, the park is directly connected to the A419 dual carriageway and has a dedicated railway siding branching off the main line.
(c) Greenfield sites are undeveloped lands. Map evidence shows it is situated on the rural-urban fringe surrounded by green forest patches/fields, and the lack of contour lines inside the park indicates flat, easy-to-build-on terrain.
(d) The commuter flow-line map shows asymmetric movement: the thickest flow-lines emerge from the west (Melton urban core), medium-width lines from southern residential suburbs, and very thin lines from rural areas north/east.

(a) 1 mark for correct 6-figure grid reference: 583192 (accept 582192 to 584192).
(b) 2 marks total: 1 mark per transport link (dual carriageway / A419 / main road, and railway / train line / railway siding).
(c) 2 marks total: 1 mark for rural-urban fringe location / surrounded by agricultural/farmland/woodland, 1 mark for flat land / lack of contour lines / easy construction terrain.
(d) 3 marks total: 1 mark for identifying major flow from West/Melton city, 1 mark for identifying secondary/moderate flow from South/suburban residential areas, 1 mark for identifying minimal/low flow from North/East/rural directions.

(a) The shaded high-risk zone for pyroclastic flows extends directly towards the North-East.
(b) The two villages situated completely inside the dark red High Hazard Zone are Rotomahana and Te Wairoa.
(c) The distance measured along line X-Y on the map is 6.4 cm. Given the 1:25000 scale (where 1 cm = 250 m), the actual distance is \(6.4 \times 250 = 1600\text{ meters}\).
(d) Planning measures visible on the map include designated evacuation roads marked with safety symbols, emergency shelters situated safely in the Low Hazard zone to the west, and a volcanological/seismic monitoring station on the ridge to capture early tremors.

(a) 1 mark for North-East (NE). Reject: East.
(b) 2 marks total: 1 mark for Rotomahana, 1 mark for Te Wairoa.
(c) 2 marks total: 1 mark for correct map measurement (6.0 to 6.8 cm), 1 mark for correct scale conversion to ground distance in meters (1500m to 1700m).
(d) 3 marks total: 1 mark for designated/signed evacuation routes, 1 mark for emergency shelter locations in low-hazard areas, 1 mark for monitoring/seismic instrumentation shown near the crater.

An exemplary response includes the following details:

(a)(i) The students would calculate a regular sampling interval by dividing the total transect length by the number of desired sites: \( \frac{8\text{ km}}{5} = 1.6\text{ km} \). Starting at the edge of the CBD (0 km), they would identify sites at fixed intervals of 1.6 km (Site 1 at 1.6 km, Site 2 at 3.2 km, Site 3 at 4.8 km, Site 4 at 6.4 km, and Site 5 at 8.0 km) using a map or GPS.

(a)(ii) Safety precautions include: 1) Wearing high-visibility jackets to ensure drivers can see them clearly. 2) Standing safely back on the pavement/footpath, well away from the road edge, during counts.

(b)(i) To ensure reliability: 1) Students should work in pairs or groups of three at each site to discuss and agree on scores, reducing personal bias. 2) They should use a detailed descriptor sheet defining exactly what features constitute a score of -2, 0, or +2. 3) They should conduct assessments at the same time of day and take multiple readings at different spots around each site, calculating an average.

(b)(ii) Advantage: EQI yields quantitative data (numerical scores) which can be easily coded, graphed, and statistically tested.
Disadvantage: The scoring system is highly subjective, and different groups of students might rate the same site differently based on personal standards or transient factors like temporary noise.

(c)(i) To ensure accuracy and comparability: 1) Count traffic at all 5 sites simultaneously (using 5 sub-groups of students). 2) Use mechanical tally counters to prevent miscounting errors. 3) Standardise the classification of vehicles beforehand (e.g., establishing a clear rule on whether to count bicycles or emergency vehicles).

(c)(ii) To construct the bar chart: 1) Label the vertical axis (y-axis) as 'Number of vehicles (per 10 minutes)' with an appropriate scale from 0 to 250. 2) Label the horizontal axis (x-axis) as 'Survey Site (Distance from CBD in km)'. 3) Plot the heights of the bars accurately: Site 1 at 240, Site 2 at 165, Site 3 at 110, Site 4 at 60, and Site 5 at 25. 4) Use uniform bar widths and leave equal gaps between the bars, adding a descriptive title.

(d)(i) Hypothesis 1 is fully supported. The data shows a continuous, direct relationship where environmental quality increases as distance from the CBD increases. At Site 1 (0.5 km from CBD), the EQI is very low at -6, whereas at the furthest point, Site 5 (7.5 km from CBD), the EQI rises to +9, representing an overall increase of \( +9 - (-6) = 15 \) index points over a distance of \( 7.5 - 0.5 = 7.0 \) km.

(d)(ii) Hypothesis 2 is fully supported. Traffic counts decrease consistently from 240 vehicles at Site 1 (0.5 km) to only 25 vehicles at Site 5 (7.5 km), showing a reduction of \( 240 - 25 = 215 \) vehicles. There is also a strong correlation between lower traffic volumes and higher environmental quality; for instance, Site 1 has the heaviest traffic (240 vehicles) and the lowest EQI (-6), while Site 5 has the lightest traffic (25 vehicles) and the highest EQI (+9).

(e) To study the sphere of influence, students could conduct questionnaires with pedestrians in the CBD to ask where they travelled from (recording their residential postcode or town name) and the frequency of their visits. They could then plot these origin points on a base map of the region and draw desire lines or a boundary (using GIS) around the furthest points of origin to delineate the CBD's catchment area.

Part (a)(i) [3 marks]:
- 1 mark for calculating/specifying a regular interval (e.g., every 1.6 km along the transect).
- 1 mark for referencing the use of a map/GPS to locate the precise sampling points.
- 1 mark for specifying the systematic spacing of the sites (e.g., 1.6, 3.2, 4.8, 6.4, 8.0 km).

Part (a)(ii) [2 marks]:
- 1 mark per valid safety precaution (e.g., high-visibility vests, remaining on the pavement, keeping in groups, avoiding peak-hour distractions near curbs). Max 2.

Part (b)(i) [3 marks]:
- 1 mark for standardising scoring beforehand (using visual or descriptive criteria for -2 to +2).
- 1 mark for group collaboration (averaging the scores of 3-4 students to reduce personal bias).
- 1 mark for spatial replication (taking multiple assessments around the site and calculating a mean).

Part (b)(ii) [4 marks]:
- 2 marks for a well-explained advantage (e.g., produces quantitative data [1] which allows easy comparison and graphing [1]).
- 2 marks for a well-explained disadvantage (e.g., subjective assessment [1] leading to inconsistent ratings between different student groups [1]).

Part (c)(i) [3 marks]:
- 1 mark for synchronisation (counting at the same time of day at all sites).
- 1 mark for accuracy tools (using tally counters or digital recorders).
- 1 mark for operational definitions (clear rules on vehicle categories to count).

Part (c)(ii) [4 marks]:
- 1 mark for correct axes labelling (y-axis: vehicle count with scale; x-axis: sites/distance).
- 1 mark for correct plotting of data points (at least 3 bars plotted accurately to score; all 5 plotted accurately for the mark).
- 1 mark for graphical conventions (even spacing, uniform bar widths).
- 1 mark for a descriptive title.

Part (d)(i) [4 marks]:
- 1 mark for stating that Hypothesis 1 is fully supported.
- 1 mark for identifying the overall trend (EQI increases as distance increases).
- 2 marks for supporting data (must cite specific distances and EQI scores, e.g., Site 1 at 0.5 km is -6, Site 5 at 7.5 km is +9, showing a change of 15 points).

Part (d)(ii) [4 marks]:
- 1 mark for stating that Hypothesis 2 is supported.
- 1 mark for referencing traffic volume decrease with distance (e.g., drops from 240 at 0.5 km to 25 at 7.5 km).
- 1 mark for linking traffic levels directly to EQI scores (e.g., high traffic of 240 correlates to low EQI of -6).
- 1 mark for quoting accurate comparative numbers/units from both datasets.

Part (e) [3 marks]:
- 1 mark for primary data collection method (questionnaires/interviews with CBD visitors).
- 1 mark for data gathered (asking for home postcode, origin town, or travel distance).
- 1 mark for mapping method (plotting desire lines, flow lines, or catchment boundaries on a base map).

An exemplary response includes the following details:

(a)(i) The method is as follows: 1) Measure out a fixed distance (e.g., 10 metres) along the beach shoreline parallel to the sea and mark the start and end points with ranging poles. 2) Stand in the water at the start point and place an orange (which acts as a highly visible float that sits low in the water) into the swash zone. 3) Start a stopwatch immediately when the float is released. 4) Stop the stopwatch when the float passes the second ranging pole and record the time in seconds. 5) Observe and record the compass direction of movement (e.g., towards the East). 6) Repeat the procedure 5 times and calculate the average speed of movement using the formula: \( \text{speed} = \frac{\text{distance}}{\text{time}} \).

(a)(ii) Natural factors: 1) Strong onshore or offshore winds can blow the exposed top of the float, causing it to deviate from the true water current. 2) Large waves can wash the float onshore onto the dry beach. To minimise these impacts, students should use a low-profile float like an orange which is almost entirely submerged, and they should perform the experiment on a calm day with typical wave conditions.

(b)(i) To measure a beach profile: 1) Lay out a safety tape measure perpendicular to the shoreline, running from the low-tide line up to the dunes. 2) Identify key 'breaks of slope' along this line. 3) Place one ranging pole at the start and another at the first break of slope. 4) Ensure both ranging poles are held vertically. 5) Use a clinometer to sight from a marked, matching height on the first pole (e.g., eye level, 1.5m) to the same height mark on the second pole, and read the angle of inclination/slope in degrees. 6) Record the distance along the tape between the poles and the angle. 7) Move the poles systematically up the beach to each consecutive break of slope and repeat the steps.

(b)(ii) A beach profile diagram should feature: 1) A continuous, sloped line representing the beach surface from the sea level (left) rising up to the dunes/cliffs (right). 2) Two vertical lines representing the ranging poles placed at different breaks of slope. 3) Annotations showing: a horizontal arrow indicating the 'tape measure measuring distance', a dashed line of sight between the two poles, and a callout showing the 'clinometer at eye level' measuring the angle of inclination in degrees.

(c)(i) To obtain a representative, unbiased sample: 1) Use a quadrat or a belt transect running from the low-water mark to the upper storm beach. 2) Generate random coordinates within the quadrat or select pebbles at fixed intervals along the transect tape (systematic sampling, e.g., every 50 cm). 3) Always pick up the pebble exactly at the intersection point without choosing based on visual appeal (e.g., picking the pebble closest to the toe of your shoe).

(c)(ii) To measure size, students should use callipers to measure the longest axis of each selected pebble in centimetres. To measure roundness, they should visually compare each pebble with a standard Powers' Scale of Roundness chart (showing visual profiles of classes 1 to 6) and assign the matching integer score.

(d)(i) On a scatter graph, pebble size (long axis in cm) would be plotted on the independent horizontal axis (x-axis) from 0 to 10 cm. The average roundness index score (from 1 to 6) would be plotted on the dependent vertical axis (y-axis). Each of the 5 sites would be plotted as a single coordinate point (e.g., Site A at (9.2, 1.8), Site E at (1.2, 5.2)), and a negative line of best fit would be drawn.

(d)(ii) Hypothesis 2 is fully supported by the data from all five sites. As we move from west to east (Site A to Site E): 1) Average pebble size decreases continuously: Site A (9.2 cm) -> Site B (7.1 cm) -> Site C (5.0 cm) -> Site D (3.2 cm) -> Site E (1.2 cm), showing an overall decrease of \( 9.2 - 1.2 = 8.0 \) cm. 2) Average roundness score increases continuously: Site A (1.8 - very angular) -> Site B (2.6) -> Site C (3.5) -> Site D (4.4) -> Site E (5.2 - well-rounded), showing an overall increase of \( 5.2 - 1.8 = 3.4 \) on the index. This matches the transport direction of longshore drift, where pebbles are progressively broken down and smoothed by attrition.

(e) Groynes block the lateral movement of sediment by longshore drift. This causes: 1) Sediment to accumulate on the updrift (western) side, making the beach wider and steeper. 2) Sediment starvation on the downdrift (eastern) side, reducing beach volume and leaving cliffs vulnerable to erosion.

Part (a)(i) [4 marks]:
- 1 mark for measuring a fixed distance (e.g., 10m) using a tape measure and marking with ranging poles.
- 1 mark for placing a suitable float (e.g., orange) in the sea/swash zone at the starting point.
- 1 mark for timing the movement using a stopwatch from start to end.
- 1 mark for recording compass direction and repeating the trial (minimum 3 times) to calculate an average.

Part (a)(ii) [3 marks]:
- 1 mark per valid natural factor (e.g., wind drag, high wave energy pushing float onshore, tidal currents). Max 2.
- 1 mark for a corresponding mitigation strategy (e.g., using a heavy, semi-submerged float like an orange; avoiding days with strong onshore winds; measuring wave frequency and repeating trials).

Part (b)(i) [5 marks]:
- 1 mark for establishing a transect line perpendicular to the sea using a tape measure.
- 1 mark for placing ranging poles at breaks of slope along the profile.
- 1 mark for measuring the linear distance between the poles along the sand.
- 1 mark for using a clinometer to measure the angle from eye level to a matching height mark on the opposite pole.
- 1 mark for systematically repeating this process for all segments from low-tide to high-tide/dunes.

Part (b)(ii) [3 marks]:
- 1 mark for identifying the key graphic elements (a profile line showing beach gradient, and vertical lines for ranging poles).
- 1 mark for annotation of distance measurement (tape measure flat along the sand).
- 1 mark for annotation of slope angle measurement (clinometer line-of-sight between identical heights on the poles).

Part (c)(i) [3 marks]:
- 1 mark for using a systematic or random sampling technique along a transect line from the sea to the dunes.
- 1 mark for avoiding selection bias (e.g., using a grid quadrat and selecting the pebble at a specific cross-wire intersection or at regular intervals like every 1 metre).
- 1 mark for sampling across different beach zones (lower, middle, upper beach) to ensure representation.

Part (c)(ii) [3 marks]:
- 1 mark for using callipers (or a ruler) to measure the long/longest axis of the pebble.
- 1 mark for using a standardised visual comparison tool (Powers' Scale of Roundness).
- 1 mark for recording the measurement units (cm/mm) and roundness score (1 to 6).

Part (d)(i) [3 marks]:
- 1 mark for stating that the x-axis represents size (cm) and the y-axis represents roundness (index 1-6).
- 1 mark for describing how the coordinates are plotted (representing the negative correlation).
- 1 mark for mentioning the inclusion of a trend line / line of best fit.

Part (d)(ii) [4 marks]:
- 1 mark for stating that Hypothesis 2 is supported.
- 1 mark for quoting size data demonstrating a decrease from west to east (e.g., Site A is 9.2 cm, Site E is 1.2 cm).
- 1 mark for quoting roundness data showing an increase from west to east (e.g., Site A is 1.8, Site E is 5.2).
- 1 mark for linking the change to coastal processes (e.g., attrition over distance as sediment is transported eastwards).

Part (e) [2 marks]:
- 1 mark for explaining that groynes block/trap sediment on the updrift side (west), building up the beach.
- 1 mark for explaining that groynes cause sediment starvation and erosion downdrift (east).