In a period, such as the present time, of growth in P and C, the latter through economic growth in the developing world, notably India and China, (and an assumption that EC is not limitless and that we may not be far short of reaching its limit) we can only move towards sustainability through a reduction in B.

How can we reduce B? There are only two appropriate routes:

Dematerialisation has, to some extent, been a natural part of our technological progress, with less and less resources (e.g. measured as amount of carbon) being used to generate a unit of activity (e.g. measured on the basis of gross domestic product). We have been progressively developing more efficient technologies and legislation and other pressures have forced the processing industries to reduce waste and to make use of that waste through recycling and reuse. However, there are conflicting societal trends that reduce these positive effects on B. Our increasing wealth has brought with it an increase in levels of consumption with individuals using their increasing wealth to buy more goods and to buy more often. The average number of cars, area of housing, quantity of clothes, food purchased and consumer goods (e.g. electronics) per person in the wealthier countries inexorably increases, while the lure of advertising encourages people to change their personal possessions at a rate way above that commensurate with the items’ wear and tear.

Transmaterialisation is a more fundamental approach to the problem, which, with the goal of sustainable development, would ultimately switch consumption to only those resources that are renewable on a short timescale. Clearly petroleum, which takes millions of years to form, is not an example of such a sustainable resource. For the method to be truly effective, the wastes associated with the conversion and consumption of such resources must also be environmentally compatible on a short timescale. The use of polyolefin plastic bags for example, which have lifetimes in the environment of hundreds of years, is not consistent with this (no matter how they compare with alternative packaging materials at other stages in their lifecycle), nor is the use of some hazardous process auxiliaries which are likely to cause rapid environmental damage on release into the environment.

While manufacturing processes have largely become more efficient, both in terms of use of resources and in terms of reduced waste, industry needs to regularly and thoroughly monitor its practises through full inventories of all inputs and outputs. Gate-to-gate environmental footprints help to identify hotspots where new technology can make a significant difference, and help to determine the value of any changes made. In chemical processes, green chemistry metrics such as mass intensity and atom efficiency need to be used alongside yield, and companies need to assist their researchers and process chemists by developing in-house guides (e.g. over choice of solvent), assessment methods, and recommended alternative reagents and technologies. In their present form, these mechanisms are, however, largely limited to further steps towards dematerialisation. Progress towards transmaterialisation requires additional features to be taken into consideration and in some cases a very different way of thinking of the problems. We must add the sustainability of all manufacturing components, inputs and outputs. Are the feedstocks for a particular manufacturing process from sustainable sources? Are the process auxiliaries sustainable? Are the process outputs – product(s) and waste – environmentally compatible e.g. through rapid biodegradation (ideally with the waste having a valuable use, even if it is a completely different application, so that the inevitable release into the environment, as is the fate for all materials, is delayed).

For organic chemicals, transmaterialisation must mean a shift from fossil (mainly petroleum) feedstocks (which have a cycle time of >10⁷ years) to plant-based feedstocks (with cycle times of <10³ years). This immediately raises several fundamentally important questions: Can we produce and use enough plants to satisfy the carbon needs of chemical and related manufacturing, while not compromising other (essentially food and feed) needs? Do we have the technologies necessary to carry out the conversions (biomass to chemicals) and in a way that does not completely compromise the environmental and transmaterialisation characteristics of the new process?

By definition, biomass corresponds to any organic matter available on a recurring basis (see Figure 1.1). The two most obvious types of biomass are wood and crops (e.g. wheat, maize and rice). Another very important type of biomass we tend to forget is waste (e.g. food waste, manure, etc). These resources are generally considered to be renewable as they can be continually re-grown/regenerated. They take up carbon dioxide from the air while they are growing (through photosynthesis) and then return it to the air at the end of life, thereby creating a ‘closed loop’ (Deswarte, 2008).

Food crops can indeed be used to produce energy (e.g. biodiesel from vegetable oil), materials (e.g. polylactic acid from corn) and chemicals (e.g. polyols from wheat). However, it is now becoming widely recognised by governments and scientists that waste and lignocellulosic materials (e.g. wood, straw, energy crops) offer a much better opportunity, since they avoid competition with the food sector and, often, do not require as much land and fertilisers to grow. In fact, only 3% of the 170 million tonnes of biomass produced yearly by photosynthesis is currently being cultivated, harvested and used (food and non-food applications) (Sanders et al., 2005). Indeed, according to a recent report published by the USDOE and the USDA (2005), the US alone could sustainably supply more than one billion dry tons of biomass annually by 2030. As seen in Table 1.2, the biomass potential in Europe is also enormous.

About 10% of all the oil we extract in the world is used to make organic chemicals and related materials. A remarkable additional 10% is used for energy to drive the chemical reactions. In the EU, this corresponded to 166 million tonnes in 2000. While increases in efficiency of chemical manufacturing in the EU have been considerable, an OECD estimate has shown that the chemical industry worldwide produces about 4% of global carbon dioxide emissions (10¹² tonnes). A shift away from fossil resources should thus benefit both resource depletion, pollution and global warming.

The figures provided by the European Biofuels Research Advisory Council (see Table 1.2) suggest an increasing potential for the conversion of biomass to biofuels in Europe over the next 20+ years, but can the European environment cope with ever-increasing biomass exploitation? We must give greater consideration to the associated stresses on large areas of land and associated systems, including water, food production and recreation (even the use of low value/waste materials such as straw and grasses will have effects). In general, when considering such enormous changes in ecosystem services exploitation we need to:

Similarly to oil-based refineries, where many energy and chemical products are produced from crude oil, biorefineries will produce many different industrial products from biomass. These will include low-value, high-volume products, such as transportation fuels (e.g. biodiesel, bioethanol), commodity chemicals, as well as materials, and high-value, low-volume products or speciality chemicals, such as cosmetics or nutraceuticals. Energy is the driver for developments in this area, but as biorefineries become more and more sophisticated with time, other products will be developed. In some types of biorefinery, food and feed production may well also be incorporated.