5.3 The rebound effect When individuals or organisations implement energy efficiency improvements, they usually save money as well as saving energy. However, if the money saved is then spent on higher standards of service, or additional energy-consuming activities that would not have otherwise been undertaken, then some or all of the energy savings may be eliminated. This tendency is sometimes known as the ‘rebound effect’. For example, if householders install improved insulation or a more efficient heating boi
4.3 Indirect use of solar energy The above examples illustrate the direct harnessing of the sun's radiant energy to produce heat and electricity. But the sun's energy can also be harnessed via other forms of energy that are indirect manifestations of its power. Principally, these are bioenergy and hydropower, already discussed in Section 3 above, together with wind energy and wave power.
3.1 Introduction So what are the principal energy systems used by humanity at present, and how sustainable are they? Until quite recently, human energy requirements were modest and our supplies came either from harnessing natural processes such as the growth of plants, which provided wood for heating and food to energise human or animal muscles, or from the power of water and wind, used to drive simple machinery.
2.4 Natural science valuation: towards ecological restoration While the previous two subsections dealt with the social sciences, the ideas of ecology represent more the natural sciences tradition. In the early years of controversy around how to practise sustainable development, some concern was expressed about the perceived bias towards social rather than natural sciences. Bryan Norton (1992), for example, is critical of the social scientific approach. He argues that reliance on standard economic and other social scientific tools will not be enough to e
2.2.3 Ecological economics Ecological economics, which formally came to prominence in the mid-1980s, represents a departure from reliance on the use of mainstream economic modelling. Instead, it branches out to actively engage with and incorporate the ethical, social and behavioural dimensions of environmental issues. In short, ecological economics attempts to provide an interdisciplinary approach to environmental issues, whereas environmental economics maintains the primacy of economic modelling. Mark Sag
2.2.2 Environmental economics and green consumerism In economic terms, green consumerism is typically expressed using measures based on the willingness to pay (WTP) principle. As mentioned above, this takes two main forms: eco-taxation, in which environmental costs are estimated and added to the price of commodities (e.g. vehicles with high carbon emissions); and eco-labelling, in which products are labelled with relevant environmental information, such as is now required by the food industry and governments in many industrialised count
2.2 Economic valuation: towards ecological economics The blue whale could have supplied indefinitely a sustainable yield of 6000 individuals a year. This is one of the earliest references to sustainability in the literature, taken from the 1971 edition of the science journal Nature (cited in Senge et al., 2006, p. 45). Here, the blue whale is given instrumental value – a means of measuring not the survival of the blue whale for its intrinsic v
1.3 The influence of environmental ethics: value and care Religious ethics can play a significant role in shaping appropriate narratives that provide for a lived ethic – that is, the obligations and entitlements associated with human relationships with Nature that embody what’s good and what’s right. But how might other ethical traditions help towards developing a lived ethic? To what extent has the emergence of environmental ethics since the 1970s influenced a lived ethic commensurate with developing care for the environment? Andrew Lig
Learning outcomes By the end of this unit you should be able to: describe environmental matters regarding obligation and entitlements from a ‘caring’ perspective; appreciate the significance of environmental consequentialist ethics in conversations around developing care; identify and compare formal and less formal expressions of environmental responsibility; understand ‘accountability’ in the context of environmental issues; ide
Introduction Nature Matters considers environmental responsibility and what may matter from a caring perspective and an accountability perspective. A reading by Andrew Light reflects on four key debates in environmental ethics regarding the way in which nature is valued, and prompts the question on how such debates might inform environmental responsibility. Section 2 examines the formal processes involved in developing accountability in the context of sustainable development. The persuasiveness of t
References 2.1 Conversing with environment Consider a situation involving what might be regarded as eco-social collapse. For example, the trigger of global warming (caused primarily by use of fossil fuels in developed countries) has encouraged the rapid development of biofuel agriculture through grants from rich countries in the global North to Brazil and other tropical countries in the global South. This has generated both ecological problems (deforestation, pesticide pollution, etc.) and socio-economic problems – particularly with 1.2 Connecting human and non-human nature Environmental responsibility – caring and generating accountability – requires interaction between human and non-human nature. For example, from a caring perspective what matters in climate change might constitute, say, the continued existence and protection of an arctic wilderness (Figure 3). But this necessarily involves a conne Learning outcomes By the end of this unit you should be able to: appreciate different connotations and traditions of the terms ‘nature’ and ‘environment’ in the context of environmental responsibility; use conversation as a core metaphor for describing ‘what matters’ in environmental responsibility; identify and compare formal and less formal expressions of environmental responsibility. 7.4 Closing thoughts Of course, doing anything about this needs scientific evidence and understanding, but it also requires social, economic and technological changes, which can only be achieved through political will. If you want to explore some of the broader context, a good place to start would be the New Internationalist issue 357, ‘The Big Switch: Climate Change Solutions’ at New Internationalist. Faced with the sort of predictions climatologists are making, is it sufficient for science teac 7.3 Running the models forward What happens when the models are run forward? It depends upon the models used and the scenarios they are asked to run. It seems almost certain, however, that there will be increases in the global mean surface temperature, to the order of +1.5 to +4.5 °C (– possibly more, according to some models and scenarios. These changes are predicted to be associated with increases in sea level, changes to weather conditions (e.g. more regular and violent winter storms in the UK) and changes to t 7.2 Comparing modelled and observed temperature The IPCC comparison between modelled and observed temperatures since the year 1860 is shown in the three charts below 7.1 Climate models To understand climate change it is necessary to construct climate models, to explore and predict interactions between different factors. Models are tested for accuracy against known sets of data, before being run forward to predict future changes. 4 Further reading For information on changes to flora, click on Science magazine. For changes to fauna, and economic effects, go to Information Sheet 4, or for the paper quoted at the top of the screen, Information Sheet 1, both at Climatic Research Unit. Click on 'View document' to open the data-smoothing information 4.5 The Kew Gardens Millennium Seed Bank Appeal
