Urban science

Last updated

Urban science is an interdisciplinary field that studies diverse urban issues and problems. Based on research findings of various disciplines such as history, economics, sociology, administration, architecture, urban engineering, transportation engineering, landscape architecture, environmental engineering, and geo-informatics, it aims to produce both theoretical and practical knowledge that contributes to understanding and solving the problems of urban issues in contemporary society. [1]

Contents

Urban science uses a computational understanding of city systems to evaluate how they work and how they are grow and change. Its aim is to make cities more habitable, resilient, and sustainable.

History

Urban science became popular with the growth of urban cities and rapid population growth. In order to understand an urban city, scientists need to gather data and statistics that enable them to determine the urban population size, median age, dominant sex, number of children born per year, yearly death rate, and many other characteristics. [2] This information enables urban scientists to predict future trends and changes, and to identify and hopefully mitigate urban challenges that are likely to arise. The more we know, the better we can prepare for the negative aspects of urban life.

The earliest signs of urban evolution appeared around 12,000 years ago. They coincided with advances in agriculture, which produced food surpluses that could be used to feed the inhabitants of towns and cities. [3] The urban population increased dramatically over time, as towns and cities attracted an increasing proportion of the overall population. Cities are currently home to around 55% of the earth’s inhabitants, [4] but account for 70% of the earth’s energy consumption, making them a major source of both air and water pollution.

Urban Cities (Megacities)

Shenzhenshi Shenzhenshi.jpg
Shenzhenshi

The central object of urban science is the study of cities. While there was only one megacity in the world in 1950, namely New York with a population of 10 million people, 34 megacities have since been created. Tokyo is currently the largest megacity, with a population of 38 million people.

Central Park CentralParkFromAboveCropped.jpg
Central Park

Scientists currently consider megacities to be unsustainable.

Urban science seeks to help cities become sustainable and habitable. Not only does it try to avoid harming the planet, but it also seeks to reverse the negative effects urban cities have already had. Urban science is intended to enhance our understanding of the urban stressors placed on the earth during the building and facilitating of urban cities. [5]

Tokyo Montage 2015 Tokyo Montage 2015.jpg
Tokyo Montage 2015

Urban Challenges

Urbanization is occurring at a rapid pace, which places pressure on urban cities to provide good living conditions for human beings. The aim of urban science is to accomplish these goals without ruining the planet. [6] Urban cities use renewable and non-renewable resources at an alarming rate. Non-renewable resources, such as fossil fuels, natural gases, and petroleum products, are by definition non-renewable and will no longer be available once they have all been consumed. [7] Moreover, renewable resources, such as water, oxygen, trees, and solar energy, require sufficient time to replenish themselves, which they are not currently being given. [8]

The current urban population is 3.9 billion people, which is expected to increase to 6 billion by 2045. Urban cities are threatened by major climate changes, and also be related events such as catastrophic storms and heat waves. They also face challenges of infrastructure development for a growing population, because the larger the population, the more housing is required for everyone. Increased construction increases the environmental changes, which impacts the climate and ecology. It also impacts the demographic characteristics of urban cities, with an increase in social inequalities, slums, and informal settlements.

Environmental Considerations

From an environmental perspective, urban science offers a systematic way of looking at the impact of urbanization on the natural world. Not all environmentalists agree with urban science and ecology, due to the negative impact it can have on the environment. However, the majority agree on the importance of finding solutions that will make the planet more sustainable, while keeping urban cities habitable. They want to ensure that the planet will not suffer from the lasting effects of urbanization and over-consumption. While continuing to acknowledge the human need to live and grow, environmentalists seek solutions to human-created problems in order to help protect the planet.

Environmentalists want to teach the rest of society about the impact human beings have on the planet. They also seek ways to improve our environmental impact, and to prevent such destruction in the future. Christopher Emdin’s 2010 journal article, Chapter Seven: What is Urban Education, indicates how urban science can be taught and used to our advantage in the future. [9] The more we know as a society about urbanization and global changes, the more aware everyone will be of our negative environmental impact. This will spark modification around the globe.

If the earth continues to be further damaged by society and over-consumption, environmentalists want to be prepared to conceptualize and facilitate the answers that can correct the damage done. They hope to reverse a proportion of this damage and to protect the environment for future generations. A large component of urban science is the study of the current environment, particularly in cities, in order to find solutions for the problems the planet faces.

Related Research Articles

<span class="mw-page-title-main">Urbanization</span> Process of population movement to cities

Urbanization is the population shift from rural to urban areas, the corresponding decrease in the proportion of people living in rural areas, and the ways in which societies adapt to this change. It can also mean population growth in urban areas instead of rural ones. It is predominantly the process by which towns and cities are formed and become larger as more people begin living and working in central areas.

<span class="mw-page-title-main">Environmental geology</span> Science of the practical application of geology in environmental problems.

Environmental geology, like hydrogeology, is an applied science concerned with the practical application of the principles of geology in the solving of environmental problems created by man. It is a multidisciplinary field that is closely related to engineering geology and, to a lesser extent, to environmental geography. Each of these fields involves the study of the interaction of humans with the geologic environment, including the biosphere, the lithosphere, the hydrosphere, and to some extent the atmosphere. In other words, environmental geology is the application of geological information to solve conflicts, minimizing possible adverse environmental degradation, or maximizing possible advantageous conditions resulting from the use of natural and modified environment. With an increasing world population and industrialization, the natural environment and resources are under high strain which puts them at the forefront of world issues. Environmental geology is on the rise with these issues as solutions are found by utilizing it.

<span class="mw-page-title-main">Resource depletion</span> Depletion of natural organic and inorganic resources

Resource depletion is the consumption of a resource faster than it can be replenished. Natural resources are commonly divided between renewable resources and non-renewable resources. The use of either of these forms of resources beyond their rate of replacement is considered to be resource depletion. The value of a resource is a direct result of its availability in nature and the cost of extracting the resource. The more a resource is depleted the more the value of the resource increases. There are several types of resource depletion, including but not limited to: mining for fossil fuels and minerals, deforestation, pollution or contamination of resources, wetland and ecosystem degradation, soil erosion, overconsumption, aquifer depletion, and the excessive or unnecessary use of resources. Resource depletion is most commonly used in reference to farming, fishing, mining, water usage, and the consumption of fossil fuels. Depletion of wildlife populations is called defaunation.

<span class="mw-page-title-main">Urban ecology</span> Scientific study of living organisms

Urban ecology is the scientific study of the relation of living organisms with each other and their surroundings in an urban environment. An urban environment refers to environments dominated by high-density residential and commercial buildings, paved surfaces, and other urban-related factors that create a unique landscape. The goal of urban ecology is to achieve a balance between human culture and the natural environment.

The ecological footprint measures human demand on natural capital, i.e. the quantity of nature it takes to support people and their economies. It tracks human demand on nature through an ecological accounting system. The accounts contrast the biologically productive area people use to satisfy their consumption to the biologically productive area available within a region, nation, or the world (biocapacity). Biocapacity is the productive area that can regenerate what people demand from nature. Therefore, the metric is a measure of human impact on the environment. As Ecological Footprint accounts measure to what extent human activities operate within the means of our planet, they are a central metric for sustainability.

<span class="mw-page-title-main">Urban geography</span> Subdiscipline of geography concentrating on urban areas

Urban geography is the subdiscipline of geography that derives from a study of cities and urban processes. Urban geographers and urbanists examine various aspects of urban life and the built environment. Scholars, activists, and the public have participated in, studied, and critiqued flows of economic and natural resources, human and non-human bodies, patterns of development and infrastructure, political and institutional activities, governance, decay and renewal, and notions of socio-spatial inclusions, exclusions, and everyday life. Urban geography includes different other fields in geography such as the physical, social, and economic aspects of urban geography. The physical geography of urban environments is essential to understand why a town is placed in a specific area, and how the conditions in the environment play an important role with regards to whether or not the city successfully develops. Social geography examines societal and cultural values, diversity, and other conditions that relate to people in the cities. Economic geography is important to examine the economic and job flow within the urban population. These various aspects involved in studying urban geography are necessary to better understand the layout and planning involved in the development of urban environments worldwide.

Technogaianism is a bright green environmentalist stance of active support for the research, development and use of emerging and future technologies to help restore Earth's environment. Technogaianists argue that developing safe, clean, alternative technology should be an important goal of environmentalists and environmentalism.

<span class="mw-page-title-main">Sustainable urban infrastructure</span>

Sustainable urban infrastructure expands on the concept of urban infrastructure by adding the sustainability element with the expectation of improved and more resilient urban development. In the construction and physical and organizational structures that enable cities to function, sustainability also aims to meet the needs of the present generation without compromising the capabilities of the future generations.

<span class="mw-page-title-main">Environmentalism</span> Philosophy about Earth protection

Environmentalism or environmental rights is a broad philosophy, ideology, and social movement about supporting life, habitats, and surroundings. While environmentalism focuses more on the environmental and nature-related aspects of green ideology and politics, ecologism combines the ideology of social ecology and environmentalism. Ecologism is more commonly used in continental European languages, while environmentalism is more commonly used in English but the words have slightly different connotations.

Human overpopulation is the idea that human populations may become too large to be sustained by their environment or resources in the long term. The topic is usually discussed in the context of world population, though it may concern individual nations, regions, and cities.

Bright green environmentalism is an environmental philosophy and movement that emphasizes the use of advanced technology, social innovation, eco-innovation, and sustainable design to address environmental challenges. This approach contrasts with more traditional forms of environmentalism that may advocate for reduced consumption or a return to simpler lifestyles.

<span class="mw-page-title-main">Ecological design</span> Design approach sensitive to environmental impacts

Ecological design or ecodesign is an approach to designing products and services that gives special consideration to the environmental impacts of a product over its entire lifecycle. Sim Van der Ryn and Stuart Cowan define it as "any form of design that minimizes environmentally destructive impacts by integrating itself with living processes." Ecological design can also be defined as the process of integrating environmental considerations into design and development with the aim of reducing environmental impacts of products through their life cycle.

This page is an index of sustainability articles.

Urban metabolism (UM) is a model to facilitate the description and analysis of the flows of the materials and energy within cities, such as undertaken in a material flow analysis of a city. It provides researchers with a metaphorical framework to study the interactions of natural and human systems in specific regions. From the beginning, researchers have tweaked and altered the parameters of the urban metabolism model. C. Kennedy and fellow researchers have produced a clear definition in the 2007 paper The Changing Metabolism of Cities claiming that urban metabolism is "the sum total of the technical and socio-economic process that occur in cities, resulting in growth, production of energy and elimination of waste." With the growing concern of climate change and atmospheric degradation, the use of the urban metabolism model has become a key element in determining and maintaining levels of sustainability and health in cities around the world. Urban metabolism provides a unified or holistic viewpoint to encompass all of the activities of a city in a single model.

<span class="mw-page-title-main">History of environmental pollution</span>

The history of environmental pollution traces human-dominated ecological systems from the earliest civilizations to the present day. This history is characterized by the increased regional success of a particular society, followed by crises that were either resolved, producing sustainability, or not, leading to decline. In early human history, the use of fire and desire for specific foods may have altered the natural composition of plant and animal communities. Between 8,000 and 12,000 years ago, agrarian communities emerged which depended largely on their environment and the creation of a "structure of permanence."

Environmentally sustainable design is the philosophy of designing physical objects, the built environment, and services to comply with the principles of ecological sustainability and also aimed at improving the health and comfort of occupants in a building. Sustainable design seeks to reduce negative impacts on the environment, the health and well-being of building occupants, thereby improving building performance. The basic objectives of sustainability are to reduce the consumption of non-renewable resources, minimize waste, and create healthy, productive environments.

<span class="mw-page-title-main">Green urbanism</span> Practice of creating communities beneficial to humans and the environment

Green urbanism has been defined as the practice of creating communities beneficial to humans and the environment. According to Timothy Beatley, it is an attempt to shape more sustainable places, communities and lifestyles, and consume less of the world's resources. Urban areas are able to lay the groundwork of how environmentally integrated and sustainable city planning can both provide and improve environmental benefits on the local, national, and international levels. Green urbanism is interdisciplinary, combining the collaboration of landscape architects, engineers, urban planners, ecologists, transport planners, physicists, psychologists, sociologists, economists and other specialists in addition to architects and urban designers.

The following outline is provided as an overview of and topical guide to environmentalism:

The desert-covered Kingdom of Saudi Arabia is the geographically largest country in the Middle East. Moreover, it accounts for 65% of the overall population of the GCC countries and 42% of its GDP. Saudi Arabia does not have a strong history in environmentalism. Thus, as the number of population increases and the industrial activity grows, environmental issues pose a real challenge to the country.

Sustainable population refers to a proposed sustainable human population of Earth or a particular region of Earth, such as a nation or continent. Estimates vary widely, with estimates based on different figures ranging from 0.65 billion people to 9.8 billion, with 8 billion people being a typical estimate. Projections of population growth, evaluations of overconsumption and associated human pressures on the environment have led to some to advocate for what they consider a sustainable population. Proposed policy solutions vary, including sustainable development, female education, family planning and broad human population planning.

References

  1. Batty, Michael (2021). "Defining Urban Science". Urban Informatics: 15–28. doi: 10.1007/978-981-15-8983-6_3 .
  2. Kitchin, R. (2016). "The Ethics of Smart Cities and Urban Science". Philosophical Transactions. Series A, Mathematical, Physical, and Engineering Sciences. 374 (2083). The Royal Society Publishing: 20160115. Bibcode:2016RSPTA.37460115K. doi:10.1098/rsta.2016.0115. PMC   5124065 . PMID   28336794.
  3. Johnson, M. T. J., Munshi-South, J. (2017). "Evolution of life in urban environments". Science. 358 (6363). University of Toronto Mississauga: eaam8327. doi: 10.1126/science.aam8327 . PMID   29097520.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  4. Meredith, S. "Two-thirds of global population will live in cities by 2050, UN says". CNBC. NBC Universal. Retrieved 2 April 2019.
  5. Edwards, P. (2016). "What is the New Urban Science?". World Economic Forum. ETH Zurich. Retrieved 12 March 2019.
  6. Timon McPhearson, T., Pickett, S. T. A., Grimm N. B., Niemelä, J., Alberti, M., Elmqvist, T., Weber, C., Haase, D., Breuste, J., Qureshi, S. (2016). BioScience, Volume 66, Issue 3: Advancing Urban Ecology toward a Science of Cities. BioScience. pp. 198–212. Retrieved 12 March 2019.{{cite book}}: CS1 maint: multiple names: authors list (link)
  7. McGarity, B. (2016). "Types of Non Renewable Resources". Renewable Green. Retrieved 12 March 2019.
  8. Aust, A. (2014). "Nonrenewable and renewable Energy Resources". KQED Science. Retrieved 12 March 2019.
  9. Emdin, C. (2010). "What is Urban Science Education?". 19 Urban Questions: Teaching in the City. Vol. 215 (Second ed.). Peter Lang AG. pp. 101–111. JSTOR   42980440.{{cite book}}: |journal= ignored (help)
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.