Can spatial patterns mitigate the urban heat island effect? Evidence from German metropolitan regions

Abstract

This study examines the efficacy of urban spatial patterns at alleviating the urban heat island (UHI) effect in Germany’s city regions (Großstadtregionen) using multivariate and non-parametric regression methods. Urban spatial patterns are quantified using five landscape metrics that capture the spatial arrangement of urban footprints and greenspaces, along with a polycentricity index that measures the distribution of human activities. The results indicate that certain features of urban fabric, including fragmentation, mixed land use, and regular-shaped urban patches, have the potential to mitigate the UHI effect. Moreover, dispersing multiple smaller greenspaces throughout the urban area demonstrates a greater cooling effect compared to having a single large and more aggregated park. In addition, our analysis reveals that a doubling (100%) of the polycentricity degree corresponds to a significant decrease in both day- and night-time UHI effects, with reductions of 10.4% and 24.6%, respectively. This study confirms that polycentric development yields greater benefits in reducing urban heat for large-sized city regions compared to medium- and small-sized ones; and its effectiveness is mostly pronounced near urban center(s). These findings suggest that polycentric development represents an efficient and feasible strategy for urban thermal planning of large-sized city regions, surpassing other commonly discussed urban configurations, such as compact or dispersed urban development.

Keywords

Urban heat island effect regional planning urban spatial pattern green space polycentricity urban development

Get full access to this article

View all access options for this article.

References

BMVBS (2006) Leitbilder und Handlungsstrategien für die Raumentwicklung in Deutschland. Verabschiedet von der Ministerkonferenz für Raumordnung am 30.06.2006. Berlin: Bundesministerium für Verkehr, Bau und Stadtentwicklung (BMVBS).

Chen

X-L

Zhao

H-M

P-X

, et al. (2006) Remote sensing image-based analysis of the relationship between urban heat island and land use/cover changes. Remote Sensing of Environment 104(2): 133–146.

Coutts

Harris

Phan

, et al. (2016) Thermal infrared remote sensing of urban heat: hotspots, vegetation, and an assessment of techniques for use in urban planning. Remote Sensing of Environment 186: 637–651.

Davoudi

(2003) European briefing: polycentricity in European spatial planning: from an analytical tool to a normative agenda. European Planning Studies 11(8): 979–999.

Debbage

Shepherd

(2015) The urban heat island effect and city contiguity. Computers, Environment and Urban Systems 54: 181–194.

Diamond

(1975) The island dilemma: lessons of modern biogeographic studies for the design of natural reserves. Biological conservation 7(2): 129–146.

ESDP (1999) ESDP - European Spatial Development Perspective: Towards Balanced and Sustainable Development of the Territory of the European Union. Luxembourg: Office for Official Publications of the European Communities.

Ewing

Rong

(2008) The impact of urban form on U.S. residential energy use. Housing Policy Debate 19(1): 1–30.

Gago

Roldan

Pacheco-Torres

, et al. (2013) The city and urban heat islands: a review of strategies to mitigate adverse effects. Renewable and Sustainable Energy Reviews 25: 749–758.

10.

Green

(2007) Functional polycentricity: a formal definition in terms of social network analysis. Urban Studies 44(11): 2077–2103.

11.

Han

Sun

Zhang

(2020) Mono- and polycentric urban spatial structure and PM2.5 concentrations: regarding the dependence on population density. Habitat International 104: 102257.

12.

Han

Kwan

M-P

, et al. (2022) Do polycentric structures reduce surface urban heat island intensity? Applied Geography 146: 102766.

13.

Z-L

(2013) Satellite-derived land surface temperature: current status and perspectives. Remote Sensing of Environment 131: 14–37.

14.

Liu

(2018) How did urban polycentricity and dispersion affect economic productivity? A case study of 306 Chinese cities. Landscape and Urban Planning 173: 51–59.

15.

Schmidt

Siedentop

(2023) Can polycentric urban development simultaneously achieve both economic growth and regional equity? A multi-scale analysis of German regions. Environment and Planning A: Economy and Space 68: 0308518X231191943.

16.

Liu

Wang

(2016) How polycentric is urban China and why? A case study of 318 cities. Landscape and Urban Planning 151: 10–20.

17.

Liu

Huang

Zhan

, et al. (2021) The influence of urban form on surface urban heat island and its planning implications: evidence from 1288 urban clusters in China. Sustainable Cities and Society 71: 102987.

18.

McGarigal

Marks

(1995) FRAGSTATS: spatial pattern analysis program for quantifying landscape structure. PNW-GTR-351. Portland, OR: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station.

19.

Meijers

Burger

(2010) Spatial structure and productivity in US metropolitan areas. Environment and Planning A: Economy and Space 42(6): 1383–1402.

20.

Milbert

(2016) Spatial Monitoring on Functional Regions in Germany. Germany: Vasab.

21.

EU Ministers (2020) Territorial Agenda 2030. A Future for All Places. Europe: EU Ministers. online. https://ec.europa.eu/regional_policy/en/information/publications/brochures/2021/territorial-agenda-2030-a-future-for-all-places.

22.

Oke

(1982) The energetic basis of the urban heat island. Quarterly Journal of the Royal Meteorological Society 108(455): 1–24.

23.

Ouwehand

van Oort

Cortinovis

(2022) Spatial structure and productivity in European regions. Regional Studies 56(1): 48–62.

24.

Pauleit

Ambrose-Oji

Andersson

, et al. (2019) Advancing urban green infrastructure in Europe: outcomes and reflections from the GREEN SURGE project. Urban Forestry and Urban Greening 40: 4–16.

25.

Schmidt

Carruthers

, et al. (2021) Planning institutions and urban spatial patterns: evidence from a cross-national analysis. Journal of Planning Education and Research 0739456X2110442.

26.

Schmidt

Siedentop

Fina

(2018) How effective are regions in determining urban spatial patterns? Evidence from Germany. Journal of Urban Affairs 40(5): 639–656.

27.

Schwarz

Manceur

(2015) Analyzing the influence of urban forms on surface urban heat islands in Europe. Journal of Urban Planning and Development 141(3): A4014003.

28.

Schwarz

Schlink

Franck

, et al. (2012) Relationship of land surface and air temperatures and its implications for quantifying urban heat island indicators—an application for the city of Leipzig (Germany). Ecological Indicators 18: 693–704.

29.

Shreevastava

Bhalachandran

McGrath

, et al. (2019) Paradoxical impact of sprawling intra-Urban Heat Islets: reducing mean surface temperatures while enhancing local extremes. Scientific Reports 9(1): 19681.

30.

Siedentop

Schmidt

Dunlop

(2022) Managing urban growth – an overview of the literature. Raumforschung und Raumordnung | Spatial Research and Planning 80(6): 659–677.

31.

Stewart

(2011) A systematic review and scientific critique of methodology in modern urban heat island literature. International Journal of Climatology 31(2): 200–217.

32.

Stone

Rodgers

(2001) Urban form and thermal efficiency: How the Design of cities Influences the urban heat island effect. Journal of the American Planning Association 67(2): 186–198.

33.

Stone

Hess

Frumkin

(2010) Urban form and extreme heat events: are sprawling cities more vulnerable to climate change than compact cities? Environmental Health Perspectives 118(10): 1425–1428.

34.

Straub

Berger

Breitner

, et al. (2019) Statistical modelling of spatial patterns of the urban heat island intensity in the urban environment of Augsburg, Germany. Urban Climate 29: 100491.

35.

Thomas

Schmidt

Siedentop

(2021) Toward Comparative Polycentricity Scores: Assessing Variations in Regional Delineation and Subcenter Identification. Environment and Planning B: Urban Analytics and City Science 48(6): 239980832110657.

36.

European Union (2011) Territorial agenda of the European Union 2020: towards an inclusive, smart and sustainable Europe of diverse regions. Planning Theory and Practice 13(3): 1–4.

37.

Yue

Qiu

, et al. (2019) Polycentric urban development and urban thermal environment: a case of Hangzhou, China. Landscape and Urban Planning 189: 58–70.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.20 MB