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Thermal Islands: Cycle C

Topic(s): No topics assigned.

 

Concepts

1). Cities are warmer than surrounding countryside. Ait temperature in a city of one million people can be up to 3 decrees C warmer during the day and as much as 12 degrees C warmer at night.

2). Human influence has made cities warmer by adding buildings, impermeable surfaces, and concrete that both produce additional heat and trap heat in the urban environment.

3). Thermal islands have downstream effects. This frequently takes the form of increased convective weather activity like thunderstorms and rain showers.

4). Urban heat islands prolong the growing season in cities. This affect diminishes away from the urban center but can affect areas as far out as 2.4 times the size of the city itself.

5). The surface urban heat island can be very pronounced during the day when temperatures of exposed surfaces like roofs and pavements can be up to 50 degrees C (90 degrees F) warmer than the surrounding air.

6). The atmospheric urban heat island tends to be weak from late morning throughout the day. It intensifies at night as heat is released from buildings and surfaces.

7). Excessive heat events (heat waves) are enhanced in urban areas resulting in increased mortality and morbidity. In the U.S. over 1,800 deaths per year may be due to urban-enhanced excessive heat events

8). Evapotranspiration is the process by which water is moved from soil through plants then is evaporated into the air. The evaporation process removes heat from the air.

9). In urban areas, surfaces that were once permeable and moist are now impermeable and dry. This adds to the build up of heat in urban areas where usually 75% or more of the surface is impermeable,allowing for much reduced evapotranspiration.

10). Whenever water undergoes a change in phase, heat is either released or absorbed.
The latent heat of condensation is the amount of heat energy released when
water goes from the vapor to the liquid phase. Conversely, the latent heat of vaporization is the amount of heat absorbed from the environment when water evaporates.

11). The albedo of a surface is the percent of incoming solar radiation that is reflected from the surface. The albedo of the Earth-atmosphere system as a whole is about 30%.

12). Specific heat capacity is the amount of energy required to raise the temperature of 1 gram of a substance 1 degree Celsius. For water, it takes one calorie (4.18 joules). For air only about 0.25 caloties(~ 1 joule) is needed

 

Scenario: A heat wave in Chicago, increased thunderstorm activity in Quincy Illinois, and fogless London days and nights – is it possible these are all related to thermal islands? What is the role of cities in our climate – and more specifically, how does the urban heat island affect climate – not only in cities but in the surrounding countryside?

Numerous studies have shown how the concrete pavements and buildings retain heat in cities, making cities several degrees warmer than the surrounding countryside. The research of Tim Oke from the University of British Columbia has shown that cities of a million people can be 1 to 3 degrees Celsius warmer than the surrounding countryside during the day and as much as 12 degrees Celsius warmer at night.

Increased morbidity and mortality rates in cities during heat waves (sometimes referred to as Excessive Heat Events or EHEs) are exacerbated by the urban heat island effect. For this and other reasons, many believe mitigation of urban heat islands should be pursued. Some strategies being recommended include increasing trees and vegetation, and developing roofs that are green and/or cool.

As cities have grown, they have warmed. One result has been a decrease in fog. London, for example, used to be known for its "pea soup" fogs, but today, dense fog is rare in the city. New York, Tokyo and Los Angeles show similar trends. According to a November, 2005 article in Nature, changes in land cover in both cities and the countryside is responsible for part of the warming the United States has experienced in the past century.

In a 2003 paper in the Journal of Applied Meteorology , Rozoff, Cotton and Adegoke demonstrated how the urban heat island of St. Louis enhanced convective activity (thunderstorms) downstream of the city.

Not all the consequences of an urban heat island are negative. For example, savings in winter heating costs, less ice and snow, and longer growing seasons in urban areas are all positive results.

 

Author: Michael Witiw, Seattle Pacific University
witiwm@spu.edu
425-898-1416


 

 

Date: 1/22/2010

 

Scenario Images

Temperature profile in the vicinity of an urban heat island
This image shows how both nocturnal and daylight temperatures vary in the vicinity of an urban heat island, and the fact that they have a different magnitude, especially in the daytime. More... Image: Courtesy: EPA (modified after Voogt, J.A., 2002: Urban heat island, in Vol. 3, Encyclopedia of Global Environmental Change, Ed. Ted Munn, John Wiley & Sons, Ltd, Chichester, 660-666)



Contributors to thermal islands
Buildings, asphalt, concrete, and industry all contribute to the Urban Heat Island by their uptake and subsequent release of heat, and, in the case of industry, by adding heat to the atmosphere. More... Image: Courtesy NASA Earth Observatory



 

Standards:

  • Science
    National Science Education Standards - Science Content Standards http://www.nap.edu/readingroom/books/nses/html/overview.html#content The science content standards outline what students should know, understand, and be able to do in the natural sciences over the course of K-12 education.
    • K-12 UNIFYING CONCEPTS AND PROCESSES
      The understandings and abilities associated with the following concepts and processes need to be developed throughout a student's educational experiences:
      • Evidence, models, and explanation
    • GRADES K-4 CONTENT STANDARDS
      • Science as Inquiry (Std A)
        • Abilities necessary to do scientific inquiry
        • Understanding about scientific inquiry
      • Physical Science (Std B)
        • Properties of objects and materials
      • Earth and Space Science (Std D)
        • Properties of earth materials
        • Changes in earth and sky
      • Science in Personal and Social Perspectives (Std F)
        • Personal health
        • Changes in environments
    • GRADES 5-8 CONTENT STANDARDS
      • Science as Inquiry (Std A)
        • Abilities necessary to do scientific inquiry
        • Understanding about scientific inquiry
      • Physical Science (Std B)
        • Properties and changes of properties in matter
        • Transfer of energy
      • Life Science (Std C)
        • Regulation and behavior
      • Science and Technology (Std E)
        • Understanding about science and technology
      • Science in Personal and Social Perspectives (Std F)
        • Personal health
        • Populations, resources, and environments
        • Natural hazards
        • Risks and benefits
    • GRADES 9-12 CONTENT STANDARDS
      • Science as Inquiry (Std A)
        • Abilities necessary to do scientific inquiry
      • Physical Science (Std B)
        • Interactions of energy and matter
      • Earth and Space Science (Std D)
        • Energy in the earth system
        • Geochemical cycles
      • Science in Personal and Social Perspectives (Std F)
        • Personal health
        • Personal and community health
        • Environmental quality
        • Natural and human-induced hazards
  • Mathematics
    Principles and Standards for School Mathematics, National Council of Teachers of Mathematics (NCTM), 2000 http://standards.nctm.org/document/prepost/cover.htm This set of Standards proposes the mathematics concepts that all students should have the opportunity to learn. Each of these ten Standards applies across all grades, prekindergarten through grade 12. Even though each of these ten Standards applies to all grades, emphases and expectations will vary both within and between the grade bands (K-2, 3-5, 6-8, 9-12). For instance, the emphasis on number is greatest in prekindergarten through grade 2, and by grades 9-12, number receives less instructional attention. Also the total time for mathematical instruction will be divided differently according to particular needs in each grade band - for example, in the middle grades, the majority of instructional time would address algebra and geometry.
    • STANDARD 2: PATTERNS, FUNCTIONS, AND ALGEBRA
      Mathematics instructional programs should include attention to patterns, functions, symbols, and models so that all students—
      • use symbolic forms to represent and analyze mathematical situations and structures;
    • STANDARD 5: DATA ANALYSIS, STATISTICS, AND PROBABILITY
      Mathematics instructional programs should include attention to data analysis, statistics, and probability so that all students—
      • pose questions and collect, organize, and represent data to answer those questions;
      • interpret data using methods of exploratory data analysis;
      • develop and evaluate inferences, predictions, and arguments that are based on data;
    • STANDARD 6: PROBLEM SOLVING
      Mathematics instructional programs should focus on solving problems as part of understanding mathematics so that all students—
      • build new mathematical knowledge through their work with problems;
      • develop a disposition to formulate, represent, abstract, and generalize in situations within and outside mathematics;
      • apply a wide variety of strategies to solve problems and adapt the strategies to new situations;
      • monitor and reflect on their mathematical thinking in solving problems.
    • STANDARD 8: COMMUNICATION
      Mathematics instructional programs should use communication to foster understanding of mathematics so that all students—
      • organize and consolidate their mathematical thinking to communicate with others;
      • express mathematical ideas coherently and clearly to peers, teachers, and others;
      • extend their mathematical knowledge by considering the thinking and strategies of others;
      • use the language of mathematics as a precise means of mathematical expression.
    • STANDARD 9: CONNECTIONS
      Mathematics instructional programs should emphasize connections to foster understanding of mathematics so that all students—
      • recognize, use, and learn about mathematics in contexts outside of mathematics.
    • STANDARD 10: REPRESENTATION
      Mathematics instructional programs should emphasize mathematical representations to foster understanding of mathematics so that all students—
      • create and use representations to organize, record, and communicate mathematical ideas;
      • use representations to model and interpret physical, social, and mathematical phenomena.
  • Geography
    Geography for Life: National Geography Standards, 1994
    • THE WORLD IN SPATIAL TERMS
      Geography studies the relationships between people, places, and environments by mapping information about them into a spatial context. The geographically informed person knows and understands:
      • How to use maps and other geographic representations, tools and technologies to acquire, process, and report information from a spatial perspective
    • PLACES AND REGIONS
      The identities and lives of individuals and people are rooted in particular places and in those human constructs called regions. The geographically informed person knows and understands:
      • The physical and human characteristics of places
    • PHYSICAL SYSTEMS
      Physical processes shape Earth’s surface and interact with plant and animal life to create, sustain, and modify ecosystems. The geographically informed person knows and understands:
      • The characteristics and spatial distribution of ecosystems on Earth’s surface
    • ENVIRONMENT AND SOCIETY
      The physical environment is modified by human activities, largely as a consequence of the ways in which human societies value and use Earth’s natural resources, and human activities are also influenced by Earth’s physical features and processes. The geographically informed person knows and understands:
      • How human actions modify the physical environment
      • How physical systems affect human systems
  • Technology
    The International Society for Technology Education From http://www.iste.org and http://www.edtech.sandi.net/index.php?option=com_docman&task=doc_download&gid=349&Itemid=229
    • SOCIAL, ETHICAL AND HUMAN ISSUES
      • Students develop positive attitudes toward technology uses that support lifelong learning, collaboration, personal pursuits, and productivity.
    • TECHNOLOGY PRODUCTIVITY TOOLS
      • Students use technology tools to enhance learning, increase productivity, and promote creativity.
    • TECHNOLOGY COMMUNICATION TOOLS
      • Students use a variety of media and formats to communicate information and ideas effectively to multiple audiences.
    • TECHNOLOGY RESEARCH TOOLS
      • Students use technology to locate, evaluate, and collect information from a variety of sources.
      • Students use technology tools to process data and report results.
    • TECHNOLOGY PROBLEM- SOLVING AND DECISION-MAKING TOOLS
      • Students use technology resources for solving problems and making informed decisions.
      • Students employ technology in the development of strategies for solving problems in the real world.

Individual Assignment
Classroom Application Cycle

This cycle you will develop cooperative activities that engage your students in understanding Earth as a system through analyzing the causes and effects of the event in this module. You also have the option of choosing a Local Event as the focus of your application. Use the resources listed below to develop your ideas. Submit your ideas for your teammates to rate and for your instructor to grade.

Assignments:

Individual:

  • Review the Individual Classroom Application and Rubric.
  • Create or adapt activities to help your students develop the concepts you have explored in this module. You may choose to do a Local Event Analysis for extra credit this cycle and then base your Classroom Application on it. If you choose to do a local event analysis and then also develop it for your classroom application, you can satisfy this cycle's requirements and receive extra credit.
  • After submitting your own classroom application to the course discussion space, recruit a classmate to rate and make comments on your classroom application. Refer to the Classroom Application Goal and Rubric.


Upload to ESSEA your classroom application with a description of its relevance to students, connection to the curriculum, instructional strategy and assessment methods. Include a reflection on what and how you have learned about Earth System Science and this event as a result of this module. Complete the rubric.
Deadline: Tuesday, March 21 2017 11:59 PM (Eastern Time)
Upload Assignments

Assessment is unavailable

Mapping Local Data in GIS (Cycle C)
From the Earth Exploration Toolbook. Explores the relation between land cover and surface air temperature.
Difficulty: advanced


Weather and the Built Environment (Cycle C)
A COMET learning module that describes weather and built environment. Includes a section on the urban heat island. Registration is required (free registration) on the Univerity Corporation for Atmospheric Research's (UCAR) meted website.
Difficulty: advanced


Digital Library for Earth System Science (Cycle C)
The ultimate resource for Earth Science lesson plans, investigations and publications.


MetEd (Cycle C)
Meterology, weather forecasting and related geoscience topics training and teaching resources. Registration is required to access modules and courses.


MY NASA DATA (Cycle C)
Lesson plans, activities, resources and more using NASA data.


NASA's Climate Kids (Cycle C)
News, information, games, teacher resources and more.


NASA's Global Climate Change (Cycle C)
Climate key indicators, evidence, effects, interactives, images and more. Educator tips and tricks for use in your classroom are provided.


Comments and Questions: essea@strategies.org
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