Climate action at the neighbourhood scale: Comparing municipal future scenarios

Yuhao Lu; Cynthia Girling; Nicholas Martino; Juchan Kim; Ronald Kellett; Jonathan Salter

doi:10.5334/bc.275

Abstract

Municipalities face the direct impact of climate change events, but many are challenged to assess the potential outcomes of future climate action policies. It is essential for local municipalities to be able to evaluate cross-sector and cross-scale policy interventions, but many lack the expertise and resources for wholistic forecasting. This paper used a hybrid inter-scalar and interdisciplinary modeling approach to evaluate, compare, visualize, and reveal the performance of climate actions at building and neighbourhood scales of future ‘what-if’ scenarios for three neighbourhood urban form types (dispersed, corridor, nodal) in three cities in British Columbia, Canada (Vancouver, Victoria, Prince George). Results found that increases in population density combined with strict building standards and retrofitting older buildings decreased per person emissions per year by up to 84% by 2050. Within the neighbourhood-scale areas, building form and location had less impact. Population density and frequency of transit service were most important for mobility mode shifts. Concentrating density at transit nodes or along commercial corridors improved the percentages of residents within a five-minute walk of those services, but proximity to greenspaces showed mixed results.

Policy relevance

Municipal climate action policies cross sectors and scales. This analysis of future urban form and energy scenarios at neighbourhood scales reveals livability and greenhouse gas (GHG) outcomes. It provides evidence that compact neighbourhood form coupled with stringent building codes reduces GHG emissions. (1) Concentrating density at transit nodes or along commercial corridors improved the percentages of residents within a five-minute walk of those services, but proximity to greenspaces showed mixed results. (2) Within neighbourhood-scale areas urban form (building form and location) had less influence on shifting mobility modes than did overall population density and transit frequency. (3) British Columbia’s net-zero-ready building code, a performance-based code, resulted in notable energy-use reductions and related emissions reductions associated with the new building stock. (4) Retrofitting the existing building stock resulted in notable emissions reductions in the three neighbourhoods; however, for cities with growing high land value, the potential for sale and redevelopment is a disincentive to retrofitting.

References

1Achtnicht, M., & Madlener, R. (2014). Factors influencing German house owners’ preferences on energy retrofits. Energy Policy, 68, 254–263. DOI: 10.1016/j.enpol.2014.01.006
Back to article
2Artmann, M., Inostroza, L., & Fan, P. (2019). Urban sprawl, compact urban development and green cities. How much do we know, how much do we agree? Ecological Indicators, 96(2), 3–9. DOI: 10.1016/j.ecolind.2018.10.059
Back to article
3Barron, S., Nitoslawski, S., Wolf, K. L., Woo, A., Desautels, E., & Sheppard, S. R. J. (2019). Greening blocks: A conceptual typology of practical design interventions to integrate health and climate resilience co-benefits. International Journal of Environmental Research and Public Health, 16(21). DOI: 10.3390/ijerph16214241
Back to article
4Baynham, M., & Stevens, M. (2014). Are we planning effectively for climate change? An evaluation of official community plans in British Columbia. Journal of Environmental Planning and Management, 57(4), 557–587. DOI: 10.1080/09640568.2012.756805
Back to article
5BC Assessment. (2019). BC Assessment—Independent, uniform and efficient property assessment. https://www.bcassessment.ca/
Back to article
6BC Climate Action Toolkit. (n.d.). https://toolkit.bc.ca/
Back to article
7BC Hydro. (n.d.). https://www.bchydro.com/powersmart/residential/rebates-programs/home-renovation/renovating-heating-system/fuel-switching.html
Back to article
8BC Transit. (2020). Open data BC Transit. https://www.bctransit.com/open-data
Back to article
9Bento, A. M., Cropper, M. L., Mobarak, A. M., & Vinha, K. (2005). The effects of urban spatial structure on travel demand in the United States. Review of Economics and Statistics, 87(3), 466–478. DOI: 10.1162/0034653054638292
Back to article
10Bibby, P., Henneberry, J., & Halleux, J. (2021). Incremental residential densification and urban spatial justice: The case of England between 2001 and 2011. Urban Studies, 58 (10), 2117–2138. DOI: 10.1177/0042098020936967
Back to article
11Breiman, L. (2001). Random forests. Machine Learning, 45(1), 5–32. DOI: 10.1023/A:1010933404324
Back to article
12Brondeel, R., Kestens, Y., & Chaix, B. (2017). An evaluation of transport mode shift policies on transport-related physical activity through simulations based on random forests. International Journal of Behavioral Nutrition and Physical Activity, 14(1), 143. DOI: 10.1186/s12966-017-0600-1
Back to article
13Canada Energy Regulator. (n.d.). https://www.cer-rec.gc.ca/en/data-analysis/energy-markets/provincial-territorial-energy-profiles/provincial-territorial-energy-profiles-british-columbia.html
Back to article
14City of Prince George. (2011). City of Prince George official community plan. https://www.princegeorge.ca/BusinessandDevelopment/Pages/PlanningandDevelopment/OfficialCommunityPlan.aspx
Back to article
15City of Prince George & OPUS International Consultants. (2010). Prince George active transportation plan. https://www.princegeorge.ca/CityServices/Documents/RoadsandTransportation/ActiveTransportation_ActiveTransportationPlan_2011.pdf
Back to article
16City of Vancouver. (n.d. a). Planning a liveable, sustainable city. https://vancouver.ca/home-property-development/urban-planning.aspx
Back to article
17City of Vancouver. (n.d. b). Greenest city action plan. https://vancouver.ca/green-vancouver/greenest-city-action-plan.aspx
Back to article
18City of Vancouver. (2012). Transportation 2040. http://vancouver.ca/files/cov/Transportation_2040_Plan_as_adopted_by_Council.pdf
Back to article
19City of Vancouver. (2017). Walk + bike + roll: Getting around the Vancouver way. https://vancouver.ca/streets-transportation/walk-bike-and-transit
Back to article
20City of Victoria. (2019). Go Victoria: Sustainable mobility strategy. https://www.victoria.ca/assets/Community/Cycling/GoVictoria_2020DEC.pdf
Back to article
21City of Victoria Planning and Development Department—Community Planning Division. (2012). City of Victoria official community plan. www.victoria.ca
Back to article
22Creatore, M. I., Glazier, R. H., Moineddin, R., Fazli, G. S., Johns, A., Gozdyra, P., Matheson, F. I., Kaufman-Shriqui, V., Rosella, L. C., Manuel, D. G., & Booth, G. L. (2016). Association of neighborhood walkability with change in overweight, obesity, and diabetes. JAMA, 315(20), 2211. DOI: 10.1001/jama.2016.5898
Back to article
23Dahmen, J., von Bergmann, J., & Das, M. (2018). Teardown index: Impact of property values on carbon dioxide emissions of single family housing in Vancouver. Energy and Buildings, 170, 95–106. DOI: 10.1016/j.enbuild.2018.03.012
Back to article
24Dale, A., Robinson, J., King, L., Burch, S., Newell, R., Shaw, A., & Jost, F. (2020). Meeting the climate change challenge: Local government climate action in British Columbia, Canada. Climate Policy, 20(7), 866–880. DOI: 10.1080/14693062.2019.1651244
Back to article
25Dixon, T., & Eames, M. (2013). Scaling up: The challenges of urban retrofit. Building Research & Information, 41(5), 499–503. DOI: 10.1080/09613218.2013.812432
Back to article
26Duncan, D. T., Aldstadt, J., Whalen, J., Melly, S. J., & Gortmaker, S. L. (2011). Validation of Walk Score^® for estimating neighborhood walkability: An analysis of four US metropolitan areas. International Journal of Environmental Research and Public Health, Basel 8(11), 4160–4179. DOI: 10.1136/bjsm.2009.069609
Back to article
27Dusyk, N., Berkhout, T., Burch, S., Coleman, S., & Robinson, J. (2009). Transformative energy efficiency and conservation: A sustainable development path approach in British Columbia, Canada. Energy Efficiency, 2(4), 387–400. DOI: 10.1007/s12053-009-9048-8
Back to article
28Energy Step Code Council. (2017). BC Energy Step Code: A best practices guide for local governments. https://www2.gov.bc.ca/assets/gov/farming-natural-resources-and-industry/construction-industry/building-codes-and-standards/guides/bcenergystepcode_guide_v1.pdf
Back to article
29Ewing, R. H. (2008). Growing cooler: The evidence on urban development and climate change. Washington, DC: Urban Land Institute.
Back to article
30Federation of Canadian Municipalities. (2010). Partners for climate protection: National measures report 2010. www.fcm.ca/pcp
Back to article
31Frank, L. D., Greenwald, M. J., Winkelman, S., Chapman, J., & Kavage, S. (2010a). Carbonless footprints: Promoting health and climate stabilization through active transportation. Preventive Medicine, 50(January), S99–S105. DOI: 10.1016/j.ypmed.2009.09.025
Back to article
32Frank, L. D., Sallis, J. F., Saelens, B. E., Leary, L., Cain, K., Conway, T. L., & Hess, P. M. (2010b). The development of a walkability index: Application to the neighborhood quality of life study. British Journal of Sports Medicine, 44(13), 924–33. DOI: 10.1136/bjsm.2009.058701
Back to article
33Frank, L. D., Schmid, T. L., Sallis, J. F., Chapman, J., & Saelens, B. E. (2005). Linking objectively measured physical activity with objectively measured urban form: Findings from SMARTRAQ. American Journal of Preventive Medicine, 28(2 Suppl. 2), 117–125. DOI: 10.1016/j.amepre.2004.11.001
Back to article
34Gamtessa, S. F. (2013). An explanation of residential energy-efficiency retrofit behavior in Canada. Energy and Buildings, 57, 155–164. DOI: 10.1016/j.enbuild.2012.11.006
Back to article
35Haaland, C., & Konijnendijk van den Bosch, C. (2015). Challenges and strategies for urban green-space planning in cities undergoing densification: A review. Urban Forestry & Urban Greening, 14(4), 760–771. DOI: 10.1016/j.ufug.2015.07.009
Back to article
36Hagenauer, J., & Helbich, M. (2017). A comparative study of machine learning classifiers for travel mode choice. Expert Systems with Applications, 78, 273–282. DOI: 10.1016/j.eswa.2017.01.057
Back to article
37Ho, T. K. (1995). Random decision forests. Proceedings of the 3rd International Conference on Document Analysis and Recognition, Montreal, QC, Canada, 14–16 August 1995 (pp. 278–282). DOI: 10.1109/ICDAR.1995.598994
Back to article
38Hsu, A., Höhne, N., Kuramochi, T., Roelfsema, M., Weinfurter, A., Xie, Y., … Widerberg, O. (2019). A research roadmap for quantifying non-state and subnational climate mitigation action. Nature Climate Change, 9(1), 11–17. DOI: 10.1038/s41558-018-0338-z
Back to article
39Hwang, W. H. (2017). Enhancing the energy conservation benefits of shade trees in dense residential developments using an alternative tree placement strategy (trans. by W. H. Hwang, P. E. Wiseman, & V. A. Thomas. Landscape and Urban Planning, 158(February), 62–74. DOI: 10.1016/j.landurbplan.2016.09.022
Back to article
40Jaccard, M. (2009). Combining top down and bottom up in energy economy models. In International Handbook on the Economics of Energy (pp. 311–331). Edward Elgar. DOI: 10.4337/9781849801997.00018
Back to article
41Jaccard, M., Murphy, R., Zuehlke, B., & Braglewicz, M. (2019). Cities and greenhouse gas reduction: Policy makers or policy takers? Journal of Energy Policy, 134, 110875. DOI: 10.1016/j.enpol.2019.07.011
Back to article
42Jost, F., Dale, A., Newell, R., & Robinson, J. (2020). Climate action assessment in three small municipalities in British Columbia: Advancements vis-à-vis major neighboring cities. Current Research in Environmental Sustainability, 2 (December), 100010. DOI: 10.1016/j.crsust.2020.100010
Back to article
43Lu, Y., Scott, A., Kim, J., Curi, C. B., McCarty, J., Pardy, A., … Girling, C. (2021). Integration of an energy–economy model with an urban energy model. Buildings and Cities, 2(1), 114. DOI: 10.5334/bc.71
Back to article
44Kavgic, M., Mavrogianni, A., Mumovic, D., Summerfield, A., Stevanovic, Z., & Djurovic-Petrovic, M. (2010). A review of bottom-up building stock models for energy consumption in the residential sector. Building and Environment, 45(7), 1683–1697. DOI: 10.1016/j.buildenv.2010.01.021
Back to article
45Majcen, D., Itard, L. C. M., & Visscher, H. (2013). Theoretical versus actual energy consumption of labelled dwellings in the Netherlands: Discrepancies and policy implications. Energy Policy, 54(March), 125–136. DOI: 10.1016/j.enpol.2012.11.008
Back to article
46Martino, N., Girling, C., & Lu, Y. (2021). Urban form and livability: Socioeconomic and built environment indicators. Buildings and Cities, 2(1), 220–243. DOI: 10.5334/bc.82
Back to article
47McCarty, J., Scott, A., & Rysanek, A. (2021). Determining the retrofit viability of Vancouver’s single-detached homes: An expert elicitation. Buildings and Cities, 2(1), 354–77. DOI: 10.5334/bc.85
Back to article
48Metro Vancouver. (2021). Energy: Discussion paper to support Climate 2050. http://www.metrovancouver.org/services/air-quality/climate-action/climate2050/regional-priorities/energy/updates/Documents/FINALClimate%202050Energydiscussionpaper%20web.pdf
Back to article
49Murphy, R., Boyd, K., & Jaccard, M. (2016). Evaluation of actions and policies to reduce urban GHG emissions using multiple criteria: A contribution towards energy efficiency in British Columbia’s built environment. EMRG Acknowledgements. https://pics.uvic.ca/sites/default/files/uploads/publications/MurphyetalUrbanEnergyLiteraturePICSAugust2016.pdf
Back to article
50Nesbitt, L., Meitner, M. J., Girling, C., Sheppard, S., Lu, Y. (2018). Who has access to urban vegetation? A spatial analysis of distributional green equity in 10 US cities. Landscape and Urban Planning, 181, 51–79. DOI: 10.1016/j.landurbplan.2018.08.007
Back to article
51Newell, R., Dale, A., & Roseland, M. (2018). Climate action co-benefits and integrated community planning: Uncovering the synergies and trade-offs. International Journal of Climate Change: Impacts and Responses, 10(4), 1–23. DOI: 10.18848/1835-7156/cgp/v10i04/1-23
Back to article
52OSMF. (2020). OpenStreetMap. openstreetmap.org
Back to article
53Reinhart, C. F., & Cerezo Davila, C. (2016). Urban building energy modeling—A review of a nascent field. Building and Environment, 97, 196–202. DOI: 10.1016/j.buildenv.2015.12.001
Back to article
54Rivers, N., & Jaccard, M. (2005). Combining top-down and bottom-up approaches to energy-economy modeling using discrete choice methods. Energy Journal, 26(1), 83–106. DOI: 10.5547/ISSN0195-6574-EJ-Vol26-No1-4
Back to article
55Rivers, N., & Jaccard, M. (2006). Useful models for simulating policies to induce technological change. Energy Policy, 34(15), 2038–2047. DOI: 10.1016/j.enpol.2005.02.003
Back to article
56Robinson, P. J., & Gore, C. D. (2005). Barriers to Canadian municipal response to climate change. Canadian Journal of Urban Research, 14(1 Suppl.), 102–120. https://www.proquest.com/scholarly-journals/barriers-canadian-municipal-response-climate/docview/208717805/se-2
Back to article
57Rutherford, S., & Counsel, S. (2009). Bill 27: Opportunities and strategies for green action by local governments. http://www.wcel.org
Back to article
58Rysanek, A. M., & Choudhary, R. (2015). DELORES—an open-source tool for stochastic prediction of occupant services demand. Journal of Building Performance Simulation, 8(2), 97–118. DOI: 10.1080/19401493.2014.888595
Back to article
59Salat, S. (2009). Energy loads, CO₂ emissions and building stocks: Morphologies, typologies, energy systems and behaviour. Building Research & Information, 37(5–6), 598–609. DOI: 10.1080/09613210903162126
Back to article
60Salter, J., Lu, Y., Kim, J. C., Kellett, R., Girling, C., Inomata, F., & Krahn, A. (2020). Iterative ‘what-if’ neighborhood simulation: energy and emissions impacts. Buildings and Cities, 1(1), 293–307. DOI: 10.5334/bc.51
Back to article
61Statistics Canada. (2016a). 2016 Census of population: Journey to work (Census of Population Statistics Canada cat. no. 98-501-X2016013). https://www12.statcan.gc.ca/census-recensement/2016/ref/98-501/98-501-x2016013-eng.cfm
Back to article
62Statistics Canada. (2016b). Dissemination area (DA)—Census dictionary. https://www12.statcan.gc.ca/census-recensement/2011/ref/dict/geo021-eng.cfm
Back to article
63Strobl, C., Boulesteix, A. L., Kneib, T., Augustin, T., & Zeileis, A. (2008). Conditional variable importance for random forests. BMC Bioinformatics, 9(1), 307. DOI: 10.1186/1471-2105-9-307
Back to article
64Tang, Z., Brody, S. D., Quinn, C., Chang, L., & Wei, T. (2010). Moving from agenda to action: evaluating local climate change action plans. Journal of Environmental Planning and Management, 53(1), 41–62. DOI: 10.1080/09640560903399772
Back to article
65Torrie, R. (2015). Low carbon futures in Canada—The role of urban climate change mitigation. Briefing on urban energy use and greenhouse gas emissions (September). www.sei-international.org
Back to article
66Ugursal, V. I., & Fung, A. S. (1996). Impact of appliance efficiency and fuel substitution on residential end-use energy consumption in Canada. Energy and Buildings, 24(2), 137–146. DOI: 10.1016/0378-7788(96)00970-X
Back to article
67Ürge-Vorsatz, D., Herrero, S. T., Dubash, N. K., & Lecocq, F. (2014). Measuring the co-benefits of climate change mitigation. Annual Review of Environment and Resources, 39, 549–582. DOI: 10.1146/annurev-environ-031312-125456
Back to article
68USGS. (2020). The national map. US Geological Survey (USGS). https://www.usgs.gov/
Back to article
69Wang, H., & Yang, Y. (2019). Neighborhood walkability: A review and bibliometric analysis. Cities, 93, 43–61. DOI: 10.1016/j.cities.2019.04.015
Back to article
70Zahabi, S. A. H., Chang, A., Miranda-Moreno, L. F., & Patterson, Z. (2016). Exploring the link between the neighbourhood typologies, bicycle infrastructure and commuting cycling over time and the potential impact on commuter GHG emissions. Transportation Research Part D: Transport and Environment, 47, 89–103. DOI: 10.1016/j.trd.2016.05.008
Back to article

Climate action at the neighbourhood scale: Comparing municipal future scenarios

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