Modelling sustainability

Bockermann, Andreas; Meyer, Bernd; Omann, Ines; Spangenberg, Joachim H.

doi:10.1016/j.jpolmod.2004.11.002

Cited by 40 publications

(2 citation statements)

References 24 publications

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“…Sterman studied growth, carrying capacity, and technology, as well as the delays in regeneration of resources, development of technologies, and adoption of policies. The carrying capacity of the earth system and detrimental effect of unsustainable growth on the environment has also been investigated with system dynamics modeled by Radzicki (19), Bueno (20), and Bockermann et al (21). System dynamics has been used to investigate the relationship between quality of life and sustainability by Beck and Stave (22,23), and Grosskurth (24) looked at a case study on regional sustainability in the Netherlands.…”

Section: System Dynamicsmentioning

confidence: 99%

Use of System Dynamics to Understand Long-Term Impact of Climate Change on Pavement Performance and Maintenance Cost

Mallick

Radzicki

Daniel

et al. 2014

Transportation Research Record: Journal of the Transportation R

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An increase in the vulnerability of the nation's roadway network to changes in climatic conditions has become an issue of significant concern. Heavy rainfall and high temperatures are examples of climatic factors that can affect pavement performance and conditions in a detrimental way. Some of these effects, specifically on costs associated with constructing and maintaining roads, may not be significant in the short term but may become significant in the long term. The objective of this study was to present a framework to use system dynamics to understand the long-term impact of climate change on pavement performance and maintenance activity. A system dynamics model was created with available pavement performance and climate change data, and the effects on various key factors, such as pavement life and maintenance cost, were evaluated through simulation. Preliminary results show that the long-term effects of changes in air temperature, rainfall, seawater–level rise, and number of hurricanes on pavement performance are significant and that costs are expected to increase significantly (>160% in 100 years) and nonlinearly. From these findings, recommendations are made for obtaining more accurate and reliable data on relevant climate change factors and for using a system dynamics approach to integrate the multi-disciplinary topics of climate change, pavement design and performance, and economics into comprehensive studies.

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Section: System Dynamicsmentioning

confidence: 99%

Use of System Dynamics to Understand Long-Term Impact of Climate Change on Pavement Performance and Maintenance Cost

Mallick

Radzicki

Daniel

et al. 2014

Transportation Research Record: Journal of the Transportation R

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“…The time dimension under systems dynamics approach it is neither given by the summa of static picture of the system in the future but it is more based on the analysis of the continuous and complex developing behaviour of the system in conjunction with its part and the external context, that it is also framed in a dynamic process of change along the time. (Richardson, 2005, Bockermann et al, 2005, Fang et al, 2005, He et al, 2006 Systems dynamics and the models from here derived offer the possibility not just to collect information about single elements but to structure knowledge and understanding of the elements of the systems and their dynamics, giving for this reason an important support for decision makers in a post-normal science era, defined by the importance and the magnitude of the stakes in relation with increasing degrees of uncertainness and complexity.…”

Section: System Thinking and Dynamicsmentioning

confidence: 99%

A resilience transition for sustainable urban development : a process design methodology to support participatory decision making

Tollin

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Actualmente, más del 50% de la población mundial vive en áreas urbanas (75% en EU), y las ciudades concentran entre un 60-80% del consumo energético global y el mismo porcentaje de las emisiones de GEI CO2. Así mismo, producen el 50% de residuos a nivel global, consumen 75% de los recursos naturales y concentran el 80% del PIB (UNEP-DTIE, 2013). -El cambio climático tiene el potencial de influir casi el total de los componentes del medio urbano y genera nuevos y complejos retos para la calidad de vida, la salud y la biodiversidad urbanas. Algunas ciudades experimentarán sequías y elevadas temperaturas. Otras podrían experimentar inundaciones. El cambio climático afectará muchos aspectos de la vida en una ciudad, desde la calidad del aire, hasta los patrones de consumo. La UE ha puesto en marcha ambiciosas políticas e iniciativas para promover soluciones sobre el terreno, entre las que se incluyen iniciativas para aumentar la resiliencia y promover tanto las energías renovables como las tecnologías de baja emisión de carbono. (EC, 2015). Las ciudades ya han comenzado a desarrollar políticas, planes y acciones específicas para la mitigación o la adaptación al cambio climático, y un relativamente pequeño pero creciente número de ellas, se encuentran liderando pioneros enfoques integrados basados en la resiliencia, que buscan responder a los retos presentados por la incertidumbre y la imprevisible naturaleza de los fenómenos que se abordan, lo cual se ve aunado a una falta de conocimiento especializado en cambio climático, en términos de investigación, evaluación, métodos, herramientas y habilidades de planeación. (EU, 2013). Haciendo una revisión en torno a los principios clave del desarrollo sostenible y a los retos clave a nivel urbano, tales como el cambio global ambiental y climático, aquí se presenta una metodología para el diseño de un proceso de transición hacia la resiliencia urbana. La metodología está basada en la amplia participación de los tomadores de decisiones, siguiendo los principios de co-diseño y co-evolución. El elemento más innovador de la metodología está relacionado con su contribución en términos de la teoría de la planeación y las prácticas para la resiliencia urbana a través de escalas tanto temporales como espaciales, lo cual se encuentra poco desarrollado actualmente. Además, el enfoque participativo del proceso de diseño redefine el rol de los planificadores aportando una perspectiva más amplia, no más como demiurgo, sino como un facilitador en los procesos de diseño y El objetivo original de la tesis, es el desarrollo de una metodología para la evaluación integrada del desarrollo urbano sostenible, expandido y ampliado para abordar la necesidad que existe, como se prueba tanto en la existencia de literatura científica como de documentos de políticas de la UE y de la ONU, de encontrar nuevas formas y métodos para la planeación en términos de resiliencia urbana, vista como un proceso dinámico y continuo de adaptación de la ciudad que permita un balance entre la necesidad de reducir el riesgo y la de innovar, todo ello para aumentar el bienestar de los ciudadanos a través de la co-evolución basada en procesos de planeación participativa. El resultado obtenido es una metodología de diseño de procesos completamente funcional para la transición hacia la resiliencia urbana, incluyendo un enfoque sistémico y un método de evaluación integrada de la sostenibilidad, el cual ha sido desarrollado desde su concepción a un Nivel de Preparación Tecnológica 7-8, finalmente incluyendo una demostración del prototipo del sistema en un ambiente operativo. Today over 50% of world population lives in urban areas (75% in EU), and cities account for 60-80% of global energy consumption and the same share of GHG CO2, producing 50% of global waste, consuming 75% of natural resources and producing 80% of global GDP. (UNEP-DTIE, 2013) ¿Climate change has the potential to influence almost all components of the urban environment and raises new, complex challenges for quality of urban life, health and urban biodiversity. Some cities will experience droughts and increased temperatures. Others may experience floods. Climate change will affect many aspects of urban living from air quality to consumption patterns. The EU has put in place ambitious policies and initiatives to promoting solutions on the ground. These include initiatives to increase resilience and promote renewable energies and low-carbon technologies. (EC, 2015) Cities have already started to develop specific mitigation or adaption or risk policies/plans/actions; and a relatively small but growing number of them are now pioneering an integrated approach urban resilience based, facing challenges related uncertainty and unpredictability of the phenomena they are addressing, and ultimately suffering for a lack of knowledge in terms of research, evaluation methods/tools and planning skills. (EU, 2013) Following a review of sustainable development principles and key urban challenges, as climate and global environmental changes, it is here presented a process design methodology for urban resilience transition. The methodology is based on broad stakeholders' participation, following co-design and co-evolution principles. The most innovative element of the process design methodology is related to the contribution in terms of planning theory and practices for urban resilience, cross-scale both in time and space, which is currently very little understood and developed. Furthermore the participatory process design approach re-define the role of planner in a wider perspective, not any longer as demiurges, but as facilitator of planning and design processes. The original objective of the thesis, to develop a methodology for integrated evaluation of sustainable urban development, was expanded and broadened to address the very needed request, as proven by both existence of scientific literature and EU/UN policy document, for new forms and methodology of planning addressing urban resilience, as a dynamic process of continuous adaptation of cities balancing between the need to reduce risk and to innovate, ultimately to increase well-being urban citizens, through co-evolution based participatory planning processes. The results is a fully working process design methodology for urban resilient transition, including the original system thinking approach and embedded with an integrated evaluation of sustainability system, which has been developed from inception to a Technology Readiness Level 7-8, finally including the system prototype demonstration in operational environment.

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Integrated scenarios for assessing biodiversity risks

Spangenberg¹

2007

Sustainable Development

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The rapid loss of biodiversity (however measured) constitutes an urgent need to develop policy strategies that reduce the anthropogenic pressures on biodiversity. To go beyond short-term curative measures, such strategies must address the driving forces causing the pressures in an integrated fashion, covering a wide range of policy domains. The development of scenarios and their illustration by modelling are essential tools to study the aggregate human impacts on biodiversity, and to derive well founded policy options to preserve it. However, so far socio-economic, climate and biodiversity models exhibit a wide range of assumptions concerning population development, economic growth and the resulting pressures on biodiversity. This paper summarizes the efforts undertaken in the framework of the ALARM project by an interdisciplinary team of economists, climatologists, land use experts and modellers to identify pressures and drivers, and to derive effective policy strategies. It describes the challenges of such a kind of work, bringing together different world views necessarily inherent to the different fields of investigation, presents preliminary results, indicates necessary policy priorities and suggests urgent issues for future research. Copyright © 2007 John Wiley & Sons, Ltd and ERP Environment.

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Modelling sustainability

Cited by 40 publications

References 24 publications

Use of System Dynamics to Understand Long-Term Impact of Climate Change on Pavement Performance and Maintenance Cost

Use of System Dynamics to Understand Long-Term Impact of Climate Change on Pavement Performance and Maintenance Cost

A resilience transition for sustainable urban development : a process design methodology to support participatory decision making

Integrated scenarios for assessing biodiversity risks

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