Open Access

This thesis justifies and develops a sustainable level of Lifestyle Material Footprint (LMF) as a benchmark for designing sustainable lifestyles. It shows the application of the benchmark in a Household-level Sustainability Transition method and presents a framework for inspiring design solutions towards a Design for One Planet (Df1P). The thesis shows how the Material Input per unit of Service (MIPS) concept has developed from product orientation to the application to household consumption and from technically-focused measurement into an integral part of methods for designing one-planet lifestyles and supporting solutions. This provides both an advanced application of the concept and its opening to new purposes and users. The core of the thesis is the suggestion of a sustainable material footprint benchmark of 8 tonnes per person per year as a resource cap target for household consumption in Finland, an 80% (factor 5) reduction from present average. The 8 tonnes benchmark opens the possibility for a target-oriented, planned reduction of LMFs by target-setting, experimenting and up-scaling of sustainable solutions. The method enabled the participating households to perform footprint reductions of 26–54% during the one-month experiment phase. Notable footprint reductions are thus possible even in the short term, which is an important message to other households and other actors in society. Calculating households' LMFs makes visible the structures underlying household consumption and the need for change not only in household consumption but also in the supply of products, services and infrastructure, and thus systemic changes initiated by others than households. The orientation framework of Df1P suggests measures that could be promoted by means of design, and structures them in a matrix incorporating priority action areas in the fields of housing, nutrition and mobility, and the domains of product design, service design, infrastructure planning and communication design. Mainstreaming sustainable lifestyles will potentially require a new design culture, but at least significant efforts in product design, service design and infrastructure planning as well as in making sustainable solutions attractive to consumers and disrupting existing routines. The more technology and infrastructure can be integrated into this change, the more space will be left for individual diversity in achieving sustainable household consumption. The orientation framework could provide a first step towards Df1P practice by inspiring designers to integrate the recognition of the planetary boundaries into their work.

In this policy paper we discuss policy instruments which can help to decarbonise passenger cars in the European Union. We elaborate to what extent these policy instruments are effective, technology-neutral, predictable, cost-effective and enforceable. Based on these criteria, we develop recommendations for the European Union and its Member States on (1) how to shape their policy frameworks in order to achieve existing climate change mitigation targets; (2) how to support car manufacturers in selling innovative and competitive products; and (3) how to encourage consumers in Europe to purchase appropriate vehicles. We conclude that favourable policy instruments are used, but there is a strong need for adjustment and further development. The effectiveness of the current EU emission standard should be further increased by turning away from granting "super-credits" and introducing a size-based (instead of weight-based) credit system. Moreover, its overall ambition is questionable and the existing compliance mechanisms should be sharpened. Fuel taxes are an effective means to push consumers to buy energy-efficient cars. However, a sharp increase may not have the desired effects. Instead, the Member States should harmonise their excise duties at the level of those Member States, which currently impose the highest taxes (Netherlands, Italy). This includes the abolition of any diesel tax bonus. An introduction and harmonisation of vehicle taxes (purchase and circulation) should be based on a vehicle's energy consumption. Additionally, reformation efforts should aim to change the taxation of company cars in a way that vehicle sizes are reduced over time. Ambitious Member States may also want to introduce a sales quota for electric vehicles. Sales quotas are a very cost-effective policy instrument provided that the mandated technology will achieve a certain market share. This may be assumed for battery-electric vehicles. Further supportive instruments that should be considered are eco-labelling, public procurement and purchase incentives. However, the latter instrument's effectiveness is debatable and its implementation should therefore not be a Member State's priority.

Sustainable Development Goal 12 (SDG 12) requires sustainable production and consumption. One indicator named in the SDG for resource use is the (national) material footprint. A method and disaggregated data basis that differentiates the material footprint for production and consumption according to, e.g., sectors, fields of consumption as well as socioeconomic criteria does not yet exist. We present two methods and its results for analyzing resource the consumption of private households based on microdata: (1) an indicator based on representative expenditure data in Germany and (2) an indicator based on survey data from a web tool. By these means, we aim to contribute to monitoring the Sustainable Development Goals, especially the sustainable management and efficient use of natural resources. Indicators based on microdata ensure that indicators can be disaggregated by socioeconomic characteristics like age, sex, income, or geographic location. Results from both methods show a right-skewed distribution of the Material Footprint in Germany and, for instance, an increasing Material Footprint with increasing household income. The methods enable researchers and policymakers to evaluate trends in resource use and to differentiate between lifestyles and along socioeconomic characteristics. This, in turn, would allow us to tailor sustainable consumption policies to household needs and restrictions.

The Port of Rotterdam is one of the pioneers in the reduction of greenhouse gas emissions. It is the largest port in Europe and extends over 40 kilometres to the North Sea coast. Its ambitious goal: the port wants to reduce greenhouse gas emissions from its industrial cluster as well as from freight traffic to a large extent. For the study "Deep Decarbonisation Pathways for Transport and Logistics Related to the Port of Rotterdam" the Wuppertal Institute analysed available options for the maritime as well was hinterland transports on behalf of the Rotterdam Port Authority. The 2050 scenarios by the Wuppertal Institute show that decarbonisation will significantly change both, volume and structure of the transported goods - which add to the on-going trend from bulk to container transport. This will have considerable structural effects on port operations and in particular on hinterland traffic. A comprehensive decarbonisation (>95 per cent) will require significant efficiency improvements through operational and technical measures and the switch to non-fossil fuels, as well as a strong shift of container transport from road transport to rail and inland navigation. For maritime shipping to and from Rotterdam two feasible pathways towards full decarbonisation by 2050 are presented. Both include a stepwise shift towards renewable electricity based energy carriers for ships (liquids and gaseous for long distances and hydrogen and electricity for shorter distances). Finally the report derives a set of recommendations for the Port Authority as well as the Dutch, German and European policymakers to support the transition towards a drastic reduction of greenhouse gase (GHG) emissions from in the transport sector and for using this as a strategy for a sustainable economic development.