Carbon dioxide (CO2) from the combustion of fossil fuels and biomass accounts for 90% of total greenhouse gas (GHG) emissions. It is thus a key factor in countries’ ability to deal with climate change. The stabilisation of GHG concentrations in the atmosphere depends on implementation of coherent national and international policies that aim at structural and technological changes. It depends on countries’ ability to further decouple CO2 and other GHG emissions growth from economic growth, and reduce the overall level of emissions.

Climate change is of global concern for its effects on ecosystems, human settlements and agriculture, and the frequency of extreme weather events. It could have significant consequences for human well-being and socio-economic activities. This, in turn, could affect global economic output.

International production networks and global value chains are increasingly interdependent. This means that domestic mitigation efforts must be placed in a global context. Further, they must build on a good understanding of carbon flows associated with international trade and final domestic demand. With increasing trade flows and the relocation of carbon-intensive production abroad, reductions in domestic emissions can be partially or wholly offset (and sometimes exceed) elsewhere in the world. The links between trade, economic growth and the environment are, however, complex. Policies must account for various factors, including pro-competitive benefits of trade for growth and development.

Achieving the aims of the 2015 Paris Agreement will require structural changes to overcome the carbon dependency of our economies. First, it will require core climate policy instruments, such as an explicit carbon price and phase out of all fossil fuel subsidies. Beyond these steps, governments must align policies across a diverse range of non-climate areas.

Carbon prices are an essential element to decarbonise the economy. They are indispensable to induce cost-effective abatement, to steer investment towards low-carbon infrastructure technologies and to discourage carbon-intensive production and consumption. Globally, countries are far from exploiting the full potential of emissions pricing policies. Most emissions across OECD and BRIICS (Brazil, the Russian Federation, India, Indonesia, the People’s Republic of China [hereafter China] and South Africa) are not priced at all, and 90% are priced at less than EUR 30 per tonne of CO2 (see chapter on Taxes and subsidies).

Current policies do not provide stable and sufficient economic incentives for firms to reduce the costs of future mitigation. Nor do they provide incentives for investments that take account of rising climate risks. Introducing a predictable long-term path of carbon prices will allow firms to adapt their investment plans to expected future increases in carbon prices. This is particularly important for investment in long-lived assets.

Progress towards green growth can be assessed against trends in CO2 emission productivity from the production and demand (footprint) perspectives, and the level of decoupling achieved between GHG emissions and economic growth. These trends can further be related to domestic objectives and international commitments and to changes in atmospheric concentrations of GHG.

CO2 emissions from energy use are still growing worldwide, mainly due to increases in transport and energy sectors. In 2014, global energy-related CO2 emissions reached a record high of 32.38 billion tonnes, or 58% more than in 1990. Production-based emissions growth has decelerated in OECD countries in the wake of the 2008 financial crises. In part, this reflects an on-going decline in the contribution of industry to overall economic activity. In BRIICS economies, emissions have continued to rise sharply (Figure 1.1).

The carbon productivity of OECD economies has improved, as CO2 emissions increased at a lower rate than real GDP (relative decoupling). Half of OECD countries have decreased emissions in absolute terms (absolute decoupling). Beyond decreases in economic activity, this reflects shifts in industrial structure, in energy supply mix and improved energy efficiency (see chapter on Energy productivity). Nine out of ten of the Nationally Determined Contributions (NDCs) submitted at the 2015 Paris Climate Summit included a reference to energy efficiency. Yet, countries such as Chile, Japan and Turkey have made limited progress in raising carbon productivity since 1995. In Saudi Arabia, Brazil and Argentina, carbon productivity has actually decreased (Figure 1.2a, Figure 1.3a).

Most reporting is based on the production perspective. This includes emissions generated on the national territory without taking trade flows into account. Countries may thus show absolute decoupling from a production perspective, but not in terms of their final demand. This is due both to changing trade patterns and to the shift of polluting industries to lower-cost locations, often with more lax environmental regulations.

A more nuanced picture thus emerges when emissions are considered from the perspective of final demand. Total emissions generated to satisfy domestic final demand in OECD countries have increased faster than emissions from domestic production. Over 1995-2011, only 12 OECD countries achieved absolute decoupling of demand-based CO2 emissions from real GDP (e.g. Denmark and Germany). This could also reflect improvements on the production side through cleaner energy use (consumption of cleaner domestic production). In three OECD countries (e.g. Norway) and three non-OECD economies (e.g. Indonesia) demand-based CO2 emissions increased faster than income (Figure 1.2b, Figure 1.3b). High oil prices in 2011 and lower export s...