Scientific and Technological Community
- Date submitted: 1 Nov 2011
- Stakeholder type: Major Group
- Name: Scientific and Technological Community
- Submission Document: Download
Full SubmissionUN Conference on Sustainable Development (Rio+20) The Scientific and Technological Community Major Group Co-organising partners: The International Council for Science (ISCU) and the World Federation of Engineering Organizations (WFEO) Input for Rio+20 Compilation Document Priority Recommendations Securing renewed political commitment ? and a new contract between science and society ? Rio+20 is a crucial opportunity for governments to recognize, enhance and map out the vital relationship between Policy-making and Science, Engineering, Technology and Innovation, within a multi and trans-disciplinary framework. ? New scientific evidence, including work on ?planetary boundaries?, reaffirms that humanity has reached a point in history at which a prerequisite for human development ? the functioning of the Earth system as we know it ? is at risk. Current economic patterns are responsible for many of the interlinked and growing social, environmental and economic crises facing the planet. The Rio+20 outcome must be commensurate with the urgent need to move humanity to a sustainable path of development. It must reflect a recognition of our planetary boundaries. Poverty eradication, human wellbeing, economic prosperity, social equity and environmental sustainability must be addressed in an integrated fashion. ? The Rio+20 conference should decide to launch a process to develop a new contract between science, engineering and society to deliver the knowledge necessary for a sustainable future. There should be a better exchange and application of existing knowledge and technology towards solutions, and support for globally coordinated research initiatives on sustainable development challenges, as well as technological innovation. Commitments in the Rio+20 outcome to significantly increased large-scale investments in targeted science (natural, social, economic, health and humanities), engineering and technology, and innovation applied to sustainable development will be a crucial element to progress. Assessing gaps in implementation ? in the light of new scientific evidence ? Implementation in many sustainable development areas has been woefully insufficient. Recognizing our planetary boundaries, policy makers need to fulfill the commitment to ?precautionary? policy as laid out in Agenda 21. Long term catastrophic risk must be balanced against short term economic implications. There is enough scientific evidence to call for immediate urgent action on climate change and other global environmental risks. Remaining gaps in knowledge cannot be taken as a reason to stall on making strong policies for sustainable development. ? Any unknowns or gaps in knowledge should be addressed through vulnerability and risk assessment techniques that also consider the economic, social and environmental impacts and the costs of ?no action? to focus evidence-based policies and enhance decisions that enable words to become actions. There is a need to strengthen Principle 10 on public participation and access to data and information, through the development of regionally and nationally appropriate mechanisms following the model of the Aarhus convention on access to information, public participation and access to justice in environmental matters. Green economy in the context of poverty eradication and sustainable development ? There is a need to develop an appropriate definition for a green economy as well as a checklist of measurable attributes that define absolute and relative progress with respect to poverty eradication and sustainable development ? There is a need for a guiding framework or principles for implementing the green economy in a way that respects the natural limits of the planet. ? Food, water, energy, resource and economic development needs should be addressed through a greening of all economic sectors. Create green economies based on ?inclusive wealth?, which includes all forms of capital ? natural, social and human as well as financial and manufactured ? and in which intergenerational wellbeing increases over time. ? Unprecedented challenges require novel, innovative responses. Rio+20 must call for incentives and much enhanced public-private funding needed to strengthen national and international systems for engineering, technology, policy, economic and social innovation to achieve sustainable development, and for novel transdisciplinary research programmes in this context. ? New scientifically sound integrated indicators should be developed to monitor progress towards sustainable development and a green economy, taking into account human wellbeing, social equity and environmental sustainability, as well as economic development. ? Targeted capacity building in science (natural, social and economic sciences), engineering and technology, including support to developing countries and attention to gender issues, will be crucial in a move towards sustainable development and a green economy. ? Unsustainable interlinked patterns of consumption, production and resource exploitation in industrialized countries and in some parts of the emerging countries should receive special attention in any roadmap to a green economy. Targeted policies and programmes to fundamentally reorient these patterns need to create synergies between government regulatory action and mobilizing civil society, business and industry. ? The activity of the Professional Engineer within the STC Major Group is mainly built on providing governments, decision makers and civil society with the elements to understand what is feasible to achieve conditions for sustainable development, and this is been done on the basis of: ? actual scientific knowledge and the limitations imposed by the laws of Nature, ? the technologies we currently possess, and ? the potential of success of technologies that are under development. ? Engineering priortities include Infrastructure engineering, disaster management, bio-engineering, energy and water availability. ? The use of any given technology requires a thorough analysis of the technological, economical, and environmental feasibility for implementing scientifically sound and efficiently engineered solutions. This includes an estimate of costs, benefits and the risks related to implementation as well as no action. Institutional Framework for Sustainable Development ? We urge decision makers to seize the opportunity of Rio+20 to develop a clear and ambitious roadmap for institutional change at all levels and bring about fundamental reform of current sustainable development and environmental governance within the next decade. ? Policies and decision making should be based on the best available natural science, social science, economic science, uptodate engineering criteria and state of the art technology. Policy making must also make full use of scientific advances and technological, economic and social innovation. Efforts to improve the institutional framework for sustainable development at all levels, and international environmental governance institutions, must therefore include strengthening of science,engineering and policy links, and strengthening the science-base and engineering capacitywithin all institutions. ? Proposals should be explored for international multistakeholder technology assessment mechanisms to evaluate the potential environmental, health, social and economic impacts of existing and new and emerging technologies, based on risk and vulnerability assessments or, if such assessments cannot be made, on the precautionary principle. ? An adequate regional governance structure for science, engineering, technology and innovation could be established by: o building partnerships with all major regional and global players; o involve international and regional non-government professional science and engineering organizations o developing and implementing instruments for regional R&D co-operation; o incorporating information systems to support decision-making, including repositories of science, engineering, technology and innovation, and policy information for social inclusion; o facilitating the establishment of problem-oriented networks for targeted research activities towards sustainable development; o contributing to the development of sustainable development indicators, including exact and natural science, engineering and technological, and social dimensions. New and emerging challenges ? Concerted, global and immediate action is needed to reduce the risk of fundamentally disrupting the stability of the Earth system, with consequences for global economic and political systems. Actions to enhance the resilience and decrease the vulnerability of human communities are also urgently needed. This must be accompanied by concerted global and enhanced action aimed at bridging the development gap between North and South and eradicating poverty, taking into account a growing world population. ? Specific topical priorities which require urgent action include: climate change, food security, water security, energy security, biodiversity loss, disaster risk reduction, and sustainable consumption and production patterns, with an overarching goal of human wellbeing, social equity and environmental and economic sustainability. ? Other immediate challenges to be addressed include: ocean acidification, pollution and overfishing; disruption of the nitrogen and phosphorus cycles; global chemical pollution; deforestation; and megacities and urbanization; all of which need action based on the latest science and technology, coordinated targeted observations and research, and improved governance. ? Addressing human health needs and concerns should be among the priority actions towards sustainable development and poverty eradication. It should also be central in addressing most if not all new and emerging challenges identified above. The increasing global mobility of people, animals and goods, as well as global warming, is leading to new disease risks in countries and regions where these diseases did not occur before. ? To help prioritize actions in these areas it is recommended that risk and vulnerability assessments be undertaken to provide the justification for decisions on implementation Climate change: ? The immediate priority is to stabilize the global climate at a temperature of no more than 2°C above pre-industrial levels. We must reduce the carbon intensity of the global economy, undertake a massive decarbonisation of the energy sector, and effectively manage Earth?s carbon and radiant energy budgets. ? Strategies for adaptation are now necessary to cope with current and future climate impacts on civil Infrastructure and natural systems. There is a need to develop the human capacity at a scientific and engineering level to effectively implement these strategies. A ?learn by doing? approach has been effective in developing the appropriate adaptation actions at the local level. Food security: ? The planet needs to feed an estimated 9 billion people by 2050. There will be a need for a knowledge-based focus on enhancing sustainable production and productivity: increasing yields while minimizing environmental footprints, and greatly reducing waste at all stages of the food chain. ? Scientific knowledge and technological development combined with engineering know-how, offers integrated and cost-effective solutions towards improving the reliability of the food supply chain in its many stages from agricultural production to the delivery to the consumer. Water security: ? An expanding population, growing economies and poor water management are putting unprecedented pressure on our freshwater resources. We simply cannot continue to use water as wastefully as we have in the past. We have to turn to a knowledge-and engineering-based approach to water conservation and management, in which we evaluate our needs, prioritise allocations, and greatly reduce waste. Biodiversity and ecosystem services: ? Current trends in biodiversity and ecosystem services are sharply and dangerously negative. We must incorporate the multiple values of biodiversity and ecosystem services into policy and management decisions, and reduce inequities in access to the benefits derived from biodiversity and ecosystem services. Energy for all: ? Efforts to provide energy for all should be based on the development and deployment of clean energy technologies focusing in particular on technologies for energy efficiency and conservation, as well as on advanced renewable energy systems. In this context, R&D and investment in renewable and alternative sources of energy should be significantly stepped up. There is also a need to develop strategies for achieving greater energy efficiency in all sectors, notably the construction and transport sectors. ? Regarding energy options, some of the technologies needed are not yet economically viable. In particular we have not yet learned to harness the abundant solar energy at a competitive cost, although costs are coming down fast. In addition, building the necessary Infrastructure to bring large scale renewable electricity from places with high yields (areas with high solar exposure or strong winds) to the places with high consumption requires huge investments and long lead times, as well as development of mechanisms to encourage Infrastructure investment. ? In addition to an increased share of renewable energy in the world?s energy mix, energy efficiency measures will help reduce the energy intensity of national economies and, therefore, slow down the increase of primary energy demand. ? End-use efficiency, power-plant efficiency, biomass, biofuels, nuclear and carbon capture and storage need to contribute. Hydro and wind power are suited to be deployed for the long term. Energy storage technologies ? e.g. pumped hydro and compressed air storage, batteries for transportation ? are key to the management of intermittent renewable energy sources. These are either mature technologies or are making big strides, while geothermal power (?hot dry rock?) still awaits the ?proof- of-concept?. Carbon capture and storage (CCS) is being developed and demonstrated at large scale. Today, wind and concentrated solar thermal power are close to being cost competitive in developed countries or in regions where other energy sources are in short supply. Disaster risk reduction: ? The world faces an increasing loss of human lives, livelihoods and economic assets due to natural and human induced disasters. There is an intrinsic relationship between disaster risk reduction, sustainable development and poverty eradication. An urgent priority is to strengthen significantly disaster preparedness using knowledge, innovation and education for effective response at all levels. ? In the case of man-made disasters, it is critical to eliminate the human cause through public safety measures, capacity building and training, and safety systems, to avoid recurrence of the disaster, or to minimize its impact without extension beyond the affected region. ? For the reason that disasters are social phenomena, both structural and non-structural measures should be applied in an integrated manner, using a social, comprehensive, and multi-disciplinary approach. Specifically, early recovery in the affected areas and societies is essential and sound reconstruction is a must to prevent disaster recurrence. ? From the aspects of project appraisal, most governments, international financial institutions and private sector entities use cost benefit analysis which, however, is inappropriate to take account factors of disaster risk management projects, especially because disaster risk management projects require prolonged terms. Private sector entities also bear social responsibilities toward prevention, reduction and mitigation of disasters. It is particularly recommended to develop other project appraisal methods than the conventional cost benefit analysis. Sustainable consumption: ? Unsustainable consumption patterns in industrialized countries and in some parts of the emerging and developing economies are one of the main factors putting increasing pressure on the planet?s social, economic and environmental systems. This requires special and urgent action. Solutions should be considered through efforts to move towards a green economy and sustainable development. Practical action, including awareness raising and education, should be underpinned by appropriate knowledge and transdisciplinary research across the multidimensional factors of economics, waste and environment, human behaviour, and lifestyle. These recommendations are taken from work by the worldwide international scientific and engineering community for Rio+20, particularly a series of regional science and technology workshops in the five UN geo-political regions (see: www.icsu.org/rio20/regional-workshops), a series of nine policy briefs prepared specifically for Rio+20 (see: www.icsu.org/rio20/policy-briefs) in the context of the Planet Under Pressure science and policy conference (London, 26-29 March 2012), and the World Engineerīs Convention -WEC2011, Geneva, 4-9 September 2011 (see Geneva Declaration: http://www.wec2011.ch/geneva-declaration/). The recommendations also draw on consultations with the constituencies of the scientific and technological community spanning all relevant disciplines in the natural, social, economic, and health sciences, and engineering disciplines in cooperation with the International Social Science Council (ISSC), UNESCO, WMO, UNEP and UNU. ICSU and WFEO have each also submitted more detailed individual recommendations to the Rio+20 process.