Title:
Urbanization and global environmental change: local effects of urban
warming.(Urbanization and global environmental change: 21st century challenges)
Date:
Introduction
The extent
and rate of global environmental changes, whether greenhouse gas-induced
warming, deforestation, desertification, or loss in biodiversity, are driven
largely by the rapid growth of the Earth's human population. Given the large and ever-increasing
fraction of the world's population living in cities, and the disproportionate
share of resources used by these urban residents, especially in the global
North, cities and their inhabitants are key drivers of global environmental
change. Here attention is directed to the impact of cities on climate. The
focus is not on the effects of cities on global-scale climate, rather the
effects globally of cities at regional and local scales. Distinct urban
climates at these scales have long been recognized (dating back to Howard
1833). Locally, they are of greater magnitude than projected global-scale
climate change and enhance the vulnerability of urban residents to future
global environmental change. Moreover, interventions at these scales have the potential
to mitigate broader environmental change both directly and indirectly.
The links between urbanization
and global climate change are complex (Sanchez-Rodriguez et al. 2005; Simon
this issue). In the context of enhanced global warming, cities
affect greenhouse gas sources and sinks both directly and indirectly.
For instance, urban areas are the major sources of anthropogenic carbon dioxide
emissions from the burning of fossil fuels for heating and cooling; from
industrial processes; transportation of people and goods, and so forth. Svirejeva-Hopkins et al. (2004) suggest that more than 90%
of anthropogenic carbon emissions are generated in cities. The clearing of land
for cities and roads, and the demand for goods and resources by urban
residents, both historically and today, are the major drivers of regional land
use change, such as deforestation, which has reduced the magnitude of global
carbon sinks.
While predicting climate change
and its impacts at a global scale is still highly uncertain, local effects of
urbanization on the climate have long been documented (see descriptions in Landsberg 1981). Surface and atmospheric changes associated
with the construction and functioning of cities are profound. New surface
materials, associated with buildings, roads, and other infrastructure, along
with changes to the morphology of the surface, alter energy and water exchanges
and airflow. Combined with direct anthropogenic emissions of heat, carbon
dioxide and pollutants, these result in distinct urban climates (Landsberg 1981; Oke 1997).
One of the best-known urban
effects of such development is urban warming; globally cities are almost always
warmer than the surrounding rural area (Oke 1973).
The magnitude of urban warming is highly variable over both time and space. On
average, urban temperatures may be 1-3[degrees]C
warmer, but under appropriate meteorological conditions (calm, cloudless nights
in winter) air temperatures can be more than 10[degrees]C warmer than
surrounding rural environments (Oke 1981). However,
in some regional settings, for example in arid environments, cities with large
amounts of irrigated greenspace (parks, suburban
vegetation) may actually be cooler than the surrounding dry areas (see the
results of Grimmond et al. 1993, for example, for
Sacramento, California, USA).
The underlying physical causes
of the urban heat island are complex (Table 1). For any neighbourhood
in any city, the relative balance of controls depends on the nature of the
urban environment, human activity, and meteorological conditions.
Urban climatologists commonly
characterize the morphology of a city in terms of the height, width and density
of buildings (see Figure 3, in which sky view factor is defined). These
properties, in combination, affect the loss of long wave radiation at night and
therefore cooling rates, the solar access during the day and thus the diurnal
pattern of heating, and airflow and wind speed at street level.
The radiative,
thermal and hydraulic properties of construction materials differ markedly from
those of bare rock, soil, vegetation and water, their pre-existing
counterparts. In many, though not all, cities the area covered by vegetation
decreases. Thus the fraction of solar energy driving evapotranspiration (the latent heat flux), rather than
warming the urban fabric and air (the sensible heat fluxes), decreases.
However, the properties of building materials differ widely (Plate 1). For
example, roofing materials--asphalt tiles, ceramic tiles, thatch, slate, and
corrugated steel/iron--have very different radiative
properties (albedo, emissivity)
and conductive properties (thermal admittance, conductivity) which greatly
affect energy uptake and release and thus heating/cooling patterns. Other
facets of buildings, for example, walls, are constructed of materials with
equally different properties, which have profound effects on heating and
cooling patterns and the resulting building and air temperatures.
[FIGURE 3 OMITTED]
[ILLUSTRATION OMITTED]
Spatial and temporal dynamics
Within a city, urban-rural
temperature differences show significant spatial and temporal variability.
Temperatures from one side of a street to the other, from a park to an
industrial neighbourhood, or one suburb to another
may be significantly different, and the nature of these differences changes
through time. Generally, the greatest intra-urban temperature differences are
associated with clear skies and low wind speeds. The clear skies allow maximum
solar radiation receipt during the day, thus enhanced heating of vertical
surfaces and roofs. Under cloudy and windy conditions there is likely to be
less solar gain and greater mixing, so that differences in air temperatures are
reduced. Typically the greatest urban-rural temperature difference is observed
2-3 h after sunset. Given that the rate of radiative
cooling is influenced by the sky view factor, narrower streets (smaller sky
view factors) result in reduced longwave radiative loss and remain warmer than more open (high sky
view factor) areas. Cities have higher building densities in the centre, so
warmer temperatures tend to be found in these locations. Changes in wind
direction, especially under low wind speed conditions, can displace these
maxima downwind. The locations of parks (vegetated) or other wide open areas
can be influential in creating complex patterns.
The magnitude of the
temperature range across a city can be very large. The range typically is
greater for surface temperatures (e.g. as seen by a satellite such as ASTER)
than for air temperatures, given that air temperatures respond to mixing. When
these spatial patterns are studied over time (seasonally, diurnally), the
location of the maximum temperature varies (e.g. Potchter
et al. 2006; Figure 4).
[FIGURE 4 OMITTED]
Urban areas are dynamic, thus
urban temperature patterns change over longer periods. Some cities develop over
time through processes of very deliberate planning, others in a more ad hoc
way. The form of urban development also varies. For example, in
Impacts
Urban warming has important
implications for human comfort, health and well-being. Many examples exist of
the vulnerability of urban populations, most often the elderly and the poor,
associated with heat waves; for example in India in 1998 and France and Spain
in 2003 (Souch and Grimmond
2004). Future climate scenarios, which predict an increase in summertime
maximum temperatures and also in the frequency and magnitude of extreme
conditions, suggest greater risks in the future. Warmer conditions in cities
will also increase demand for air conditioning. More air conditioners generate more
heat and have significant effects on the local-scale external climate, with
implications for human comfort and the demand for cooling. At a larger scale,
greater use of air conditioning results in more greenhouse gases through
increased electricity generation. Significant growth in the use of air
conditioning in North America, Europe and Asia has been documented and recent
simulations indicate the resultant increase in energy demand will more than
offset reductions in energy demand for heating under cold conditions (Hadley et
al. 2006).
Mitigation
Understanding the causes of the
urban heat island effect allows insight into strategies for mitigation. This
has broader implications in terms of the management of energy resources. Peak
energy demand for many regions of the world is now in the summer rather than
winter. On occasions, utility companies are now unable to meet demand under
these conditions and blackouts or rolling-blackouts result. For example, during
some of the warmer periods of the summer of 2006, energy supply in
A wide range of strategies is
being considered to mitigate urban warming (Table 1). The scales at which these
can be applied vary; for example, individual building versus a neighbourhood, new development versus
redevelopment/retrofitting. Some mitigation strategies involve changing the
material properties of individual buildings (e.g. Akabari
et al. 2001), others to the spatial arrangement (separation of individual
buildings). Changes in materials have the advantage that they can be used on
current buildings, so do not require the costs or time of new development.
Moreover, significant developments in new building materials mean that many
that have high reflectivity and modified emissivity
no longer need to be 'white'. Thus individual preferences in terms of colour can be retained (Cool Roof Rating Council 2006). In
many cases, new materials may cost no more than the traditional alternatives.
Hence cost is not a barrier to integration of 'cool' building materials.
Many strategies benefit
multiple aspects of urban environmental change. For example, the addition of
water detention ponds and wetlands reduces peak urban runoff, which has the
advantages of reducing the need to engineer larger systems to deal with flash
floods and/or manage the release of untreated water downstream. With careful
design of a wetland area, the quality of the stormwater
can also be enhanced as well as providing the open areas of parks (higher sky
view factors) and enhanced evaporation. Additional social, cultural, and
psychological benefits from 'natural' space can accrue too. Also, new
residential developments (e.g. Lynbrooks in
Melbourne, Australia) employ water-sensitive urban design that involves the use
of grey water to irrigate residential vegetation (Mitchell et al. 2002). This
reduces the demand for water to be diverted into a city for irrigation
purposes.
Other strategies involve
developing district heating and cooling (DHC) using combined heat and power
(CHP) or co-generation systems. These aim to reduce the emissions of carbon
dioxide and other air pollutants (IEA 2006) and have been developed for
building to (small) citywide scales (they can generate several kilowatts to
hundreds of megawatts of electricity). Technological changes are increasing the
viability of these systems; notably reducing energy losses in the transmission
process, and by recapturing waste heat and energy to avoid warming the air
unnecessarily. The captured heat can be used to meet heating requirements,
provide cooling using advanced absorption cooling technology, and also to
generate more electricity with a steam turbine.
Final comments
Clearly the direct
contributions of urban warming to global climates are small. Urban areas cover
only a small fraction on the Earth's surface and their moisture, thermal and kinematic effects extend downwind only a few kilometres. However, the greenhouse gas emissions from the
construction and operation of cities are large and increasing; the gases from
urban areas are the dominant anthropogenic sources. Moreover, the warmer
conditions in many cities result in greater energy and resource consumption by
the inhabitants to offset the effect and also make urban populations more
vulnerable to heat waves and other extreme conditions. Thus it is critical that
cities and the drivers of urbanization are central to global environmental
research. Urban areas and urban populations will continue to grow in size and
number. Existing urban areas will experience redevelopment and refurbishment.
The decisions made about how this will occur will impact upon the people living
within the buildings, neighbourhoods and cities. In
combination, they will have global implications and consequences.
References
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SUE GRIMMOND
Environmental Monitoring and Modelling Group, Department of Geography, King's College
London, Strand, London WC2R 2LS
E-mail: sue.grimmond@kcl.ac.uk
This paper was accepted for
publication in January 2007
Table 1 Causes of urban warming and examples of mitigation strategies
Urban heat island causes Mitigation strategy Increased surface area
Large vertical faces
Reduced sky view factor
Increased absorption of shortwave High reflection building and road
(solar) radiation materials, high reflection
Decreased longwave (terrestrial) paints for vehicles
radiation loss Spacing of buildings
Decreased total turbulent heat Variability of building heights
transport
Reduced wind speeds Surface materials
Thermal characteristics
Higher heat capacities Reduce surface temperatures
Higher conductivities (changing albedo and
Increased surface heat storage emissivity)
Improved roof insulation Moisture characteristics
Urban areas have larger areas that Porous pavement are impervious Neighbourhood detention ponds and
Shed water more rapidly--changes wetlands which collect
the hydrograph stormwater
Increased runoff with a more rapid Increase greenspace fraction
peak Greenroofs, greenwalls
Decreased evapotranspiration
(latent heat flux, [Q.sub.E])
Additional supply of energy--
anthropogenic heat flux--[Q.sub.F]
Electricity and combustion of fossil Reduced solar loading internally, fuels: heating and cooling systems, reduce need for active cooling
machinery, vehicles. (shades on windows, change
3-D geometry of buildings--canyon materials) geometry District heating and cooling
systems
Combined heat and power systems
High reflection paint on vehicles to reduce temperature
Air pollution
Human activities lead to ejection of District heating and cooling pollutants and dust into the systems
atmosphere Combined heat and power or
Increased longwave radiation from cogeneration systems
the sky
Greater absorption and re-emission ('greenhouse effect')
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