Urban Areas (HL IB ESS OLD COURSE - IGNORE)
Revision Note
Written by: Alistair Marjot
Reviewed by: Bridgette Barrett
Understanding Urban Areas
What is an urban area?
An urban area is a built-up environment with:
A high population density
A large concentration of buildings and man-made infrastructure
Urban areas serve as centres for residential, cultural, economic, trade and social activities
Cities, towns and suburbs are examples of urban areas
Urban areas contrast with rural areas
Rural areas have:
Lower population densities
More dispersed settlements, often focused on agriculture and natural landscapes
For example, London, UK, is a large urban area with dense population, infrastructure and cultural hubs whereas the Lake District in the UK is a rural area with scattered villages and a focus on agriculture and tourism
Urban ecosystems
Urban ecosystems are unique environments found within cities and towns
They occur where human activities interact with natural elements like plants, animals and climate
These ecosystems have both biotic components (living organisms like plants, animals and humans) and abiotic components (non-living parts like soil, water, air and urban infrastructure).
Types of urban ecosystems
Residential gardens:
Gardens found in residential areas are important urban ecosystems, providing habitats for plants, birds, insects and small mammals
These areas also help to improve air quality and reduce the effects of urban heat islands
Industrial sites:
Industrial areas include factories, warehouses and other business operations
These areas may cause pollution, but some are now being redeveloped with green spaces to improve the environment
Inner-city derelict land:
Abandoned or derelict land in cities can become important for wildlife and urban regeneration projects
These areas often develop biodiversity as nature reclaims the land
Green areas and open spaces:
Urban parks and green spaces are essential ecosystems, offering habitats for animals, improving air quality and providing recreational space for people
Traffic corridors:
Areas alongside roads and railways form their own ecosystems, with hardy plants and animals that can survive in polluted or disturbed environments
Urban planners can design green corridors along these routes to help connect different wildlife habitats within cities
Cemeteries:
Cemeteries are often quiet, green spaces within urban areas that support a wide range of plant and animal life
They can act as biodiversity hotspots, with trees, grass and other vegetation supporting birds, insects and small mammals
Waste disposal areas:
Landfills and waste treatment plants are part of urban ecosystems
Although they can cause pollution, they are also home to certain species of birds, insects and bacteria that thrive in waste environments
Forests, fields and water bodies:
Some urban areas contain patches of forests, fields, lakes or rivers, which provide crucial habitats for wildlife and help with urban temperature regulation
Components of urban ecosystems
Biotic components:
Plants (trees, shrubs, grass) found in parks, gardens and along streets
Animals such as birds, insects and mammals
Humans, whose activities like construction, gardening and commuting shape the ecosystem
Microorganisms, including bacteria and fungi that break down waste and enrich soil
Abiotic components:
Soil: essential for plant growth in urban parks and gardens
Water: found in rivers, lakes and urban infrastructure like water supply systems
Air: clean air is important for health but urban areas often face challenges with air pollution
Climate: urban areas often create a microclimate, with higher temperatures due to buildings and infrastructure
Urban infrastructure: buildings, roads, bridges and other structures are integral to urban ecosystems, affecting how people and nature interact
Examiner Tips and Tricks
Make sure you can clearly explain the differences between urban and rural areas in terms of population density, infrastructure, and ecosystem types.
Urban Systems
An urban system is a network of interconnected elements that work together to support life in a city or town
Urban systems involve:
Buildings
Transport
Power and energy supply
Water supply
Sewage systems
Plants and animals
Humans
Components of urban systems
Buildings and infrastructure
Buildings form the core of an urban system, providing residential, commercial and industrial spaces
Infrastructure such as roads, bridges and utilities (electricity, water and waste) connects and supports the functioning of the urban area
Transport
Urban areas rely on transport systems like roads, railways and buses to move people and goods
Efficient transport systems are essential to reduce traffic congestion and air pollution
For example, London’s Underground is a major part of the city's urban transport system, helping to reduce road traffic
Power and energy
Urban systems require energy to power homes, businesses and industries
This energy can come from fossil fuels, nuclear power or renewable sources
Ensuring a reliable and sustainable energy supply is vital for cities to function properly
Water and sewage
Water supply systems provide clean water for drinking, washing and other daily needs
Sewage systems remove and treat wastewater to prevent pollution and maintain hygiene
Microclimate
Cities create their own microclimates
They often become warmer than surrounding rural areas (urban heat island effect)
This is due to the high concentration of human activities and infrastructure
Urban planners consider green spaces and certain building designs and materials to manage urban microclimates
Humans, plants and animals
Urban systems support human populations, as well as urban wildlife and plants in parks, gardens and green areas
These living (biotic) components of urban ecosystems provide recreational spaces and contribute to air quality and biodiversity
Other factors in urban systems
Urban waste and pollution
Cities generate large amounts of waste and pollution, including solid waste, air pollution and water contamination
Managing waste and reducing pollution is critical to maintaining urban efficiency and public health
Urban efficiency
Urban efficiency refers to how well a city uses its resources, including energy, water and transport systems
More efficient urban systems can reduce waste, cut down pollution and improve quality of life for residents
Urban sustainability
Sustainability is about ensuring that urban systems can meet the needs of the present without harming future generations
Sustainable cities focus on reducing their environmental impact by using renewable energy, reducing waste and promoting green spaces
Urban systems can operate with different types of resource management
They might follow either a linear or circular metabolism approach, which affects sustainability and waste management in cities
Linear metabolism cities:
These are cities that follow a 'take, use, dispose' approach
Resources (like energy and water) are used once and then discarded as waste
This leads to high levels of consumption and pollution
Circular metabolism cities:
These are cities that focus on recycling, reusing, and reducing waste
This approach aims to minimise resource use by creating a closed-loop system where outputs (like waste) are reused as inputs (e.g. recycling materials or generating energy from waste)
Urban resilience
Resilience refers to a city's ability to recover from challenges like natural disasters, climate change or economic crises
Resilient urban systems have strong infrastructure, emergency services and disaster preparedness plans
For example, after Hurricane Katrina (2005), the city of New Orleans, USA, improved its flood defences and urban infrastructure to increase resilience against future disasters
Urban system flow diagram
An urban system can be represented using a systems flow diagram by showing how resources (inputs) move through the city, are used, and generate outputs like waste and pollution
Inputs: the resources a city needs to function
Examples: energy (electricity, fuel), water, food, goods (materials for buildings and infrastructure), and labour (human workforce)
Processes: how the city uses these inputs in its daily operations
Examples: buildings, transport systems, services (healthcare, education), and infrastructure (roads, power plants, water supply)
Outputs: the results of urban processes, often in the form of waste
Examples: solid domestic waste (rubbish, recycling), pollution (air and water), and sewage
Feedback: information or actions that help the system improve in efficiency, sustainability, and resilience
Examples: urban planning decisions (like building more green spaces), implementing renewable energy, and waste management initiatives
Awaiting image: Urban system flow diagram
Image caption: Cities of different types, as well as other urban systems such as towns or industrial sites, can be represented using system flow diagrams
Examiner Tips and Tricks
Urban areas work as systems, so be sure you can explain how the various parts of an urban system—like transport, energy, and waste—interact with each other. For example, as urban systems are highly interconnected, you could be asked to explain how improvements in one area (e.g. transport) can positively affect other areas (e.g. pollution).
Don’t confuse terms like efficiency, sustainability, and resilience!
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