Many economists argue that the most effective policy for dealing with climate change is carbon pricing. This reduces greenhouse gas (GHG) emissions in a way that minimises the costs to the economy.
For the policy to work effectively it is important that the price per tonne of CO2 equivalent (CO2e) does not vary with the activity that causes the emissions. In other words, whether you drive a car, heat your house using gas or travel by air, the GHGs you create need to be priced at a unified rate.
Governments can introduce carbon pricing in two different ways – cap-and-trade schemes and carbon taxes.
With a cap-and-trade policy, emission allowances are either issued or sold to the organisations covered by the scheme. They must accumulate enough of these allowances to match the actual level of emissions they produce or pay a large fine. After the initial allocation, allowances can be bought and sold in a secondary market and prices can be quite volatile.
With a carbon tax, the government directly sets the price of GHGs through the tax rate but has less control over the quantity of emissions.
Policy in the UK
The UK Emissions Trading Scheme – an example of a cap-and-trade scheme – clearly places a price on GHG emissions. As this price is determined by market forces it can vary on a daily basis. The scheme applies to electricity generation and other energy-intensive industries that account for approximately 30 per cent of all emissions.
Although the UK does not have a specific carbon tax, it does have a number of different taxes that have an impact on the environment. Some of these have stated environmental objectives (e.g. the Climate Change Levy) while the main rationale for others is to raise revenue (fuel duty).
The tax rates are typically set on the output or consumption of the good rather than on emissions. For example, the Climate Change Levy applies to businesses’ use of electricity, gas and coal rather than the emissions the energy generates. Fuel duty depends on the amount of petrol consumed rather than the emissions the burning of that fuel generates. Clearly, emissions will tend to rise in proportion to the consumption/production of the good, but the relationship will not be precise.
The structure of VAT also influences emissions. The standard rate of VAT in the UK is 20 per cent. However, a lower level is applied to some goods/services that produce significant emissions. For example, the rate on household consumption of gas is 5 per cent while commercial passenger flights are zero rated. These lower tax rates are an implicit subsidy for the people who consume these goods/services. It makes them cheaper relative to the price of other goods.
Impact of the policies
Researchers from the Institute for Fiscal Studies have recently tried to analyse the impact of this complex range of policies on the price of carbon. The results indicate wide variations depending on the activity that causes the emissions.
One of the most significant differences is between gas and electricity. For example, non-energy-intensive businesses pay a price of £229.10 per tonne of CO2e from electricity generation but only £30.50 per tonne from burning gas. The response to the incentives this creates is unsurprising. One of the biggest contributing factors to the fall in territorial emissions in the UK has come from the decarbonisation of electricity supply: i.e. the switch away from coal-fired generation.
The impact of government policy on UK households creates quite perverse incentives. Because of the lower rates of VAT, families receive an implicit subsidy of £24 per tonne CO2e when they use gas to heat their homes. When they use electricity, the source of energy that generates less emissions, they face a positive price of £137 per tonne of CO2e. Once again, the response to these incentives is unsurprising. Household emissions only fell by a relatively small amount between 1990 and 2018 because of the continued use of gas for heating and cooking.
Unsurprisingly many commentators have referred to carbon pricing in the UK as a confusing mess and have called for a unified rate across all activities to minimise the costs to the economy. Another important issue is the level at which a new unified rate is set. Some research by the Department for Business, Energy and Industrial Strategy suggests that the figure would have to be set between £122 and £36 per tonne of CO2e in order for the UK to reach its target of net zero emissions by 2050.
A higher unified rate would also create another problem – the distributional impact. Poorer households spend a much greater share of their income on electricity, heating and food and so would be disproportionately affected by the policy. For the policy to be politically acceptable, the government will need to find an effective way to compensate these groups.
Articles
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Questions
- Outline the difference between territorial and consumption emissions.
- Using the concepts of rivalry and excludability, explain why GHGs and the climate change they cause are an example of market failure.
- Discuss the main differences between cap-and trade schemes and carbon emission taxes.
- Explain why a unified carbon price would minimise the costs to the economy of reducing the level of GHG emissions.
- Discuss some of the potential limitations of introducing carbon pricing and explain why some countries are considering the implementation of a Carbon Border Adjustment mechanism.
The development of open-source software and blockchain technology has enabled people to ‘hack’ capitalism – to present and provide alternatives to traditional modes of production, consumption and exchange. This has enabled more effective markets in second-hand products, new environmentally-friendly technologies and by-products that otherwise would have been negative externalities. Cryptocurrencies are increasingly providing the medium of exchange in such markets.
In a BBC podcast, Hacking Capitalism, Leo Johnson, head of PwC’s Disruption Practice and younger brother of Boris Johnson, argues that various changes to the way capitalism operates can make it much more effective in improving the lives of everyone, including those left behind in the current world. The changes can help address the failings of capitalism, such as climate change, environmental destruction, poverty and inequality, corruption, a reinforcement of economic and political power and the lack of general access to capital. And these changes are already taking place around the world and could lead to a new ‘golden age’ for capitalism.
The changes are built on new attitudes and new technologies. New attitudes include regarding nature and the land as living resources that need respect. This would involve moving away from monocultures and deforestation and, with appropriate technologies (old and new), could lead to greater output, greater equality within agriculture and increased carbon absorption. The podcast gives examples from the developing and developed world of successful moves towards smaller-scale and more diversified agriculture that are much more sustainable. The rise in farmers’ markets provides an important mechanism to drive both demand and supply.
In the current model of capitalism there are many barriers to prevent the poor from benefiting from the system. As the podcast states, there are some 2 billion people across the world with no access to finance, 2.6 billion without access to sanitation, 1.2 billion without access to power – a set of barriers that stops capitalism from unlocking the skills and productivity of the many.
These problems were made worse by the response to the financial crisis of 2007–8, when governments chose to save the existing model of capitalism by propping up financial markets through quantitative easing, which massively inflated asset prices and aggravated the problem of inequality. They missed the opportunity of creating money to invest in alternative technologies and infrastructure.
New technology is the key to developing this new fairer, more sustainable model of capitalism. Such technologies could be developed (and are being in many cases) by co-operative, open-source methods. Many people, through these methods, could contribute to the development of products and their adaptation to meet different needs. The barriers of intellectual property rights are by-passed.
New technologies that allow easy rental or sharing of equipment (such as tractors) by poor farmers can transform lives and massively increase productivity. So too can the development of cryptocurrencies to allow access to finance for small farmers and businesses. This is particularly important in countries where access to traditional finance is restricted and/or where the currency is not stable with high inflation rates.
Blockchain technology can also help to drive second-hand markets by providing greater transparency and thereby cut waste. Manufacturers could take a stake in such markets through a process of certification or transfer.
A final hack is one that can directly tackle the problem of externalities – one of the greatest weaknesses of conventional capitalism. New technologies can support ways of rewarding people for reducing external costs, such as paying indigenous people for protecting the land or forests. Carbon markets have been developed in recent years. Perhaps the best example is the European Emissions Trading Scheme (EMS). But so far they have been developed in isolation. If the revenues generated could go directly to those involved in environmental protection, this would help further to internalise the externalities. The podcasts gives an example of a technology used in the Amazon to identify the environmental benefits of protecting rain forests that can then be used to allow reliable payments to the indigenous people though blockchain currencies.
Podcast
Questions
- What are the main reasons why capitalism has led to such great inequality?
- What do you understand by ‘hacking’ capitalism?
- How is open-source software relevant to the development of technology that can have broad benefits across society?
- Does the current model of capitalism encourage a self-centred approach to life?
- How might blockchain technology help in the development of a more inclusive and fairer form of capitalism?
- How might farmers’ co-operatives encourage rural development?
- What are the political obstacles to the developments considered in the podcast?
The transition towards clean energy in combination with a shortfall in supply has seen the price of raw uranium, also known as ‘yellowcake’, rise almost 60 per cent in recent weeks. It is now trading at over $50 a pound – a nine-year high. The market has been described as being at a ‘tipping point’. Given the recent boom in the market, the current conditions could tip the balance towards an era of rising uranium prices.
What is uranium?
Uranium is a heavy metal which has been used as a source of concentrated energy for over 60 years. Uranium ore can be mined from underground, milled, and then sold. It is then used in a nuclear reactor for electricity generation. About 10% of the world’s electricity is generated from uranium in nuclear reactors. There are some 445 nuclear reactors operating in 32 countries. It is the most energy-dense and efficient fuel source we have, with just ten uranium pellets able to power the average household for an entire year.
In March 2011, Japan’s most powerful earthquake on record triggered a tsunami, which then caused a meltdown at a nuclear power plant in Fukushima. It forced residents from their homes as radiation leaked from the plant. Since the Fukushima accident, uranium prices had been on a downtrend trend – enough to force several miners to suspend or scale back operations.
However, there has been a 42 per cent increase in the price of the metal in the first nine months of 2021 alone.
Demand for uranium
Since launching in July, a new investment trust, run by Canadian asset manager Sprott, has snapped up about 6m pounds of physical uranium, worth about $240m. This aggressive buying has helped push prices of uranium to more than $40 per pound, up from $30 at the start of the year. In the first part of September alone, prices surged by around 40%, outperforming all other major commodities. In just a few weeks, millions of pounds of supply were scooped up by the Sprott Physical Uranium Trust. This puts pressure on utilities that need to secure supplies of the commodity for electricity generation.
This increased demand is occurring at precisely the same time as countries and companies around the world are committing to net-zero carbon targets. As a result, nuclear power companies are now facing competition for supplies of uranium from financial investors, who are betting on sharply higher prices and demand for the radioactive material used to fuel reactors. This boost in demand is said to be due to uranium being used as a low-carbon energy source, despite the radioactive waste problem that comes with it. Investors are betting that nuclear power will be a key part of the move away from fossil fuels.
Production from world uranium mines has in recent years supplied 90% of the requirements of power utilities for uranium, with the current global mine supply expected to be about 125m pounds for 2021. In addition, there are secondary sources such as commercial and military stockpiles. However, according to the World Nuclear Association, demand for uranium is expected to climb from about 162m pounds this year to 206m pounds in 2030, and to 292m pounds by 2040. This is largely driven by increased power generation in China. China is planning a big increase in its nuclear power capacity over the next decade as the country seeks to cut its emissions.
Supply of uranium
Although uranium is relatively abundant in the Earth’s crust, not all uranium deposits are economically recoverable. While some countries have uranium resources that can be mined profitably when prices are low, others do not. Kazakhstan is the largest producer of uranium and in 2019 produced more uranium than the second, third, and fourth-largest producers combined.
The big issue is that supply to the market is falling significantly. For deliveries that would start in 2022, Kazakh producer, Kazatomprom, is now discussing the possibility of supplying the metal directly to Sprott. However, it also warned of the risk that its mines would not reach their output target for 2021, and it said earlier this year that it would keep its production at reduced levels through 2023. In addition to this, the recent surge in buying is also reducing the inventories that accumulated after the Fukushima accident.
The supply of uranium is set to fall 15 per cent by 2025 and by 50 per cent by 2030. This is mainly due to a lack of investment in new mines. The lack of new uranium mines will mean the price has to move higher. Namibian mines, accounting for 8 per cent of world supply, are approaching the end of their lives. Cameco of Canada, another important source, has shut one large pit because of uneconomic prices. According to BMO Capital, a mine supply deficit since 2019 will continue.
Supply has also been affected by the pandemic. The boom in demand has coincided with historically low prices and pandemic-driven mine disruptions, prompting uranium producers to buy from the spot market to fulfil long-term contracts with consumers. Some of the largest mining operations in Canada and Kazakhstan had to suspend production temporarily due to a shortage of workers.
Adding to the security of supply concerns is the role of commercial and state-owned entities in the uranium market. Uranium is a highly trade-dependent commodity with international trade policies highlighting the disconnect between where uranium is produced and where it is consumed. About 80% of primary production comes from countries that consume little-to-no uranium, and nearly 90% of uranium consumption occurs in countries that have little-to-no primary production. As a result, government-driven trade policies can be particularly disruptive for the uranium market. It is argued that the risk to uranium supply may create a renewed focus on ensuring availability of long-term supply to fuel nuclear reactors.
The role of financial players
Financial players have been accelerating the recent recovery in the price of uranium, with large-scale speculative buying and withholding of supply. But it can be argued that this would not have occurred if there were not a fundamental and substantial shortage.
If investors keep buying uranium, analysts expect utility companies will come under pressure to replace long-term supply agreements before they expire. At the moment, long-term contracts cover 98 per cent of the uranium needed by US utility companies. But that figure drops to 84 per cent next year, and 55 per cent by 2025, according to uranium investment company, Yellow Cake.
As annual supply declines, demand for uranium from producers and financial players increases, and with trade policy potentially restricting access to some markets, it is believed the pounds available in the spot market will not be adequate to satisfy the growing backlog of long-term demand. As a result, companies expect there will be increased competition to secure uranium under long-term contracts on terms that will ensure the availability of reliable primary supply to meet growing demand.
What will the future look like?
Many countries are turning their attention to nuclear power in order to become net-zero economies. Even in Japan, nuclear generation has slowly been returning. It is argued that nuclear power is needed to some degree for the country to achieve its pollution-curbing goals. However, not all nations are re-embracing nuclear. Germany, for example, is set to shut its last reactor next year.
The concern is whether the recent gains in investor demand is enough to underpin the market. It can be argued that even before the recent price rally started, demand for uranium from the investment sector was already growing. However, observers of the market have suggested that just as quickly as uranium skyrocketed, prices may now be hitting the brakes. Producer stocks that got swept up in the frenzy seem to have peaked. In addition, the world’s top uranium miner Kazatomprom has warned that the recent price action was being fuelled by financial investors rather than the utilities that use the radioactive metal as fuel in their reactors. On the other hand, it is argued that this pickup in the spot market will be the catalyst to push more utilities to get involved in term contracting.
Despite the impact of the pandemic on global energy demand, it is now growing again. Gas and other energy shortages are being seen and the price of gas has been rising rapidly. This rise in energy prices plus a focus on carbon-free generation is likely to continue driving demand for nuclear power and hence for uranium. In addition, producers have warned of supply shortages in the long term as investors scoop up physical inventory and new mines are not starting quickly enough. Thus nuclear’s growing role in the clean energy transition, in addition to a supply shortfall, could turn the tide for the uranium industry.
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Data
Questions
- Using the uranium market as an example, describe the relationship between an increase in demand and the market price.
- Explain whether the supply of uranium would be price elastic or inelastic in (a) the short run; (b) the long run.
- What is the role of speculation in determining the recent movements in the price of uranium and likely future price movements?
- Given your answers to the above questions, draw supply and demand diagrams to illustrate (a) the recent increase in the market price of uranium; (b) the likely price of uranium in five years from now.
For many goods and services, economists argue that relatively unregulated markets often do a pretty good job in delivering desirable outcomes from society’s view point.
However, for these desirable outcomes to occur, certain conditions need to be present. One of these is that all the benefits and costs of consuming and producing the good/service must be experienced/incurred by the buyers and sellers directly involved in the transaction: i.e. there are no externalities. The market can still work effectively if people outside of the transaction are affected (i.e. third parties) but the impact occurs through the price mechanism.
The fast fashion industry
Fast fashion refers to designs and trends that rapidly pass from catwalks and designers to retailers. The clothes sell for low prices and in high quantities. The business model relies on regular purchases and impulse buying. It is particularly popular in the UK where annual clothing consumption per capita is significantly greater than in other European countries – 26.7kg vs 16.7kg in Germany and 14.5kg in Italy. On average, people in the UK have 115 items of clothing. Unsurprisingly, 30 per cent of these garments have not been worn for at least 12 months.
Externalities in fast fashion
There is lots of evidence that the fast fashion market fails to meet the condition of no externalities. Instead, it generates lots of external costs across its whole supply chain that do not affect third parties through the price mechanism. For example:
- Growing cotton requires large amounts of water. Some estimates suggest that on average it takes 10 000 litres of water to cultivate just one kilogram of cotton. As water is a common resource (rival and non-excludable), its use in cotton production can exceed socially desirable levels. This can have serious consequences for both the quantity of drinking and ground water and can lead to previously fertile land being transformed into arid regions that are too dry to support vegetation.
- Growing cotton also uses large amounts of pesticide. Some estimates suggest that 6 per cent of global pesticide production is applied to cotton crops. Extended contact with these chemicals can cause illness and infertility. It also has a negative impact on the long-term productivity of the soil. For example, the chemicals destroy microorganisms, plants and insects and so decrease biodiversity.
- The manufacture of synthetic fibres such as polyester has a smaller negative impact on the use of water and land than the cultivation of a natural fibre such as cotton. However, because it is derived from oil, its manufacture generates more CO2 emissions. One study compared the CO2 emissions from producing the same shirt using polyester and cotton. The former generated 5.5kg whereas the latter produced 2.1kg.
- The waste water from the use of solvents, bleaches and synthetic dyes in the manufacture of textiles/garments often flows untreated into local rivers and water systems. This is especially the case in developing countries. Estimates suggest that this is responsible for between 17 and 20 per cent of industrial global water pollution.
- There are excessive levels of textile waste. This can be split into producer waste and consumer waste. Producer waste consists of 10–15 per cent of the fabric used in the manufacture of garments that ends up on the cutting room floor. It also includes deadstock – unsold and returned garments. For example, Burberry admitted that in 2017 it incinerated £28.6 million of unsold stock. In the same year, UK consumers disposed of 530 000 tonnes of unwanted clothing, shoes, bags and belts. This all went for landfill and incineration.
- Textiles are one of the major sources of microplastic pollution and contribute 35 per cent (190 000 tonnes) of microplastic pollution in the oceans. A 6kg domestic wash can release as many as 700 000 synthetic fibres.
Addressing the externalities
The House of Commons Environmental Audit Committee published a report on the fashion industry in February 2019. One of its key recommendations was that the tax system should be reformed so that it rewards fashion companies that design products with lower environmental impacts.
The UK government has tended to focus on the use of plastic rather than textiles. For example, it introduced a charge for single use carrier bags as well as banning the use of microbeads in rinse-off personal products and plastic straws/stirrers.
In April 2022, a new tax is being introduced in the UK on the plastic packaging of finished goods that is either manufactured in the UK or imported from abroad. The rate, set at £200 per metric tonne, will apply to packaging that contains less than 30 per cent of recycled plastic.
One specific proposal made by the Environmental Audit Committee was for the government to consider extending this new tax to textiles that contain less than 50 per cent recycled polyester. A recent study found that just under 50 per cent of clothes for sale on leading online websites were made entirely from new plastics.
The committee also called for the introduction of an extended producer responsibility scheme. This would make textile businesses responsible for the environmental impact of their products: i.e. they would have to contribute towards the cost of collecting, moving, recycling and disposing of their garments. It could involve the payment of an up-front fee, the size of which would depend on the environmental impact of the product.
In its Waste Prevention Programme for England published in March 2021, the government announced plans to consult with stakeholders about the possibility of introducing an ‘extended producer responsibility scheme’ in the textile industry. The House of Commons Environmental Audit Committee is also carrying out a follow-up inquiry to its 2019 report.
Articles
Government and Parliament documents and reports
Questions
- Using the concepts of rivalry and excludability, define the concept of a common resource.
- Explain the ‘tragedy of the commons’ and how it might apply to the use of water in the cultivation of cotton.
- Draw a diagram to illustrate how negative externalities in consumption and production lead to inefficient levels of output in an unregulated competitive market.
- Using a diagram, explain how imposing a tax on producers of textile products that contain less than 50 per cent recycled polyester could reduce economic inefficiency.
- Explain the potential limitations of using taxation/regulation to address the pollution issues created by the fast fashion sector.
The UN’s Intergovernmental Panel on Climate Change (IPCC) has just published the first part of its latest seven-yearly Assessment Report (AR6) on global warming and its consequences (see video summary). The report was prepared by 234 scientists from 66 countries and endorsed by 195 governments. Its forecasts are stark. World temperatures, already 1.1C above pre-industrial levels, will continue to rise. This will bring further rises in sea levels and more extreme weather conditions with more droughts, floods, wildfires, hurricanes and glacial melting.
The IPCC looked at a number of scenarios with different levels of greenhouse gas emissions. Even in the most optimistic scenarios, where significant steps are taken to cut emissions, global warming is set to reach 1.5C by 2040. If few or no cuts are made, global warming is predicted to reach 4.4C by 2080, the effects of which would be catastrophic.
The articles below go into considerable detail on the different scenarios and their consequences. Here we focus on the economic causes of the crisis and the policies that need to be pursued.
Global success in reducing emissions, although partly dependent on technological developments and their impact on costs, will depend largely on the will of individuals, firms and governments to take action. These actions will be influenced by incentives, economic, social and political.
Economic causes of the climate emergency
The allocation of resources across the world is through a mixture of the market and government intervention, with the mix varying from country to country. But both market and government allocation suffer from a failure to meet social and environmental objectives – and such objectives change over time with the preferences of citizens and with the development of scientific knowledge.
The market fails to achieve a socially efficient use of the environment because large parts of the environment are a common resource (such as the air and the oceans), because production or consumption often generates environmental externalities, because of ignorance of the environmental effects of our actions, and because of a lack of concern for future generations.
Governments fail because of the dominance of short-term objectives, such as winning the next election or appeasing a population which itself has short-term objectives related to the volume of current consumption. Governments are often reluctant to ask people to make sacrifices today for the future – a future when there will be a different government. What is more, government action on the environment which involves sacrifices from their own population, often primarily benefit people in other countries and/or future generations. This makes it harder for governments to get popular backing for such policies.
Economic systems are sub-optimal when there are perverse incentives, such as advertising persuading people to consume more despite its effects on the environment, or subsidies for industries producing negative environmental externalities. But if people can see the effects of global warming affecting their lives today, though fires, floods, droughts, hurricanes, rising sea levels, etc., they are more likely to be willing to take action today or for their governments to do so, even if it involves various sacrifices. Scientists, teachers, journalists and politicians can help to drive changes in public opinion through education and appealing to people’s concern for others and for future generations, including their own descendants.
Policy implications of the IPCC report
At the COP26 meeting in Glasgow in November, countries will gather to make commitments to tackle climate change. The IPCC report is clear: although we are on course for a 1.5C rise in global temperatures by 2040, it is not too late to take action to prevent rises going much higher: to avoid the attendant damage to the planet and changes to weather systems, and the accompanying costs to lives and livelihoods. Carbon neutrality must be reached as soon as possible and this requires strong action now. It is not enough for government to set dates for achieving carbon neutrality, they must adopt policies that immediately begin reducing emissions.
The articles look at various policies that governments can adopt. They also look at actions that can be taken by people and businesses, actions that can be stimulated by government incentives and by social pressures. Examples include:
- A rapid phasing out of fossil fuel power stations. This may require legislation and/or the use of taxes on fossil fuel generation and subsidies for green energy.
- A rapid move to green transport, with investment in charging infrastructure for electric cars, subsidies for electric cars, a ban on new petrol and diesel vehicles in the near future, investment in hydrogen fuel cell technology for lorries and hydrogen production and infrastructure, cycle lanes and various incentives to cycle.
- A rapid shift away from gas for cooking and heating homes and workplaces and a move to ground source heating, solar panels and efficient electric heating combined with battery storage using electricity during the night. These again may require a mix of investment, legislation, taxes and subsidies.
- Improvements in energy efficiency, with better insulation of homes and workplaces.
- Education, public information and discussion in the media and with friends on ways in which people can reduce their carbon emissions. Things we can do include walking and cycling more, getting an electric car and reducing flying, eating less meat and dairy, reducing food waste, stopping using peat as compost, reducing heating in the home and putting on more clothes, installing better insulation and draught proofing, buying more second-hand products, repairing products where possible rather than replacing them, and so on.
- Governments requiring businesses to conduct and publish green audits and providing a range of incentives and regulations for businesses to reduce carbon emissions.
It is easy for governments to produce plans and to make long-term commitments that will fall on future governments to deliver. What is important is that radical measures are taken now. The problem is that governments are likely to face resistance from their supporters and from members of the public and various business who resist facing higher costs now. It is thus important that the pressures on governments to make radical and speedy reductions in emissions are greater than the pressures to do little or nothing and that governments are held to account for their actions and that their actions match their rhetoric.
Articles
Some climate changes now irreversible, says stark UN reportChannel 4 News, Alex Thomson (9/8/21)
- Climate change: IPCC report is ‘code red for humanity’
BBC News, Matt McGrath (10/8/21)
- Climate change: Five things we have learned from the IPCC report
BBC News, Matt McGrath (10/8/21)
- Climate Scientists Reach ‘Unequivocal’ Consensus on Human-Made Warming in Landmark Report
Bloomberg Green, Eric Roston and Akshat Rathi (9/8/21)
- Climate change: Seven key takeaways from the IPCC climate change report
Sky News, Philip Whiteside (10/8/21)
- IPCC report: global emissions must peak by 2025 to keep warming at 1.5°C – we need deeds not words
The Conversation, Keith Baker (9/8/21)
- This is the most sobering report card yet on climate change and Earth’s future. Here’s what you need to know
The Conversation, Pep Canadell, Joelle Gergis, Malte Meinshausen, Mark Hemer and Michael Grose (9/8/21)
- IPCC report: how to make global emissions peak and fall – and what’s stopping us
The Conversation, Matthew Paterson (9/8/21)
- World’s 1.5C goal slipping beyond reach without urgent action, warns landmark IPCC climate report
Independent, Daisy Dunne and Louise Boyle (9/8/21)
- IPCC report: 14 ways to fight the climate crisis after publication of ‘Code Red’ warning
Independent, Harry Cockburn (10/8/21)
- Major climate changes inevitable and irreversible – IPCC’s starkest warning yet
The Guardian, Fiona Harvey (9/8/21)
- Climate scientists have done their bit. Now the pressure is on leaders for COP26.
CNN, Ivana Kottasová and Angela Dewan (10/8/21)
- 21 For 21: The Climate Change Actions Scotland Needs Now
Common Weal, Common Weal Energy Policy Group (9/8/21)
- How to build support for ambitious climate action in 4 steps
The Conversation, Sarah Sharma and Matthew Hoffmann (4/3/21)
- Scientists have finally added world politics to their climate models
Quartz, Michael J Coren (9/8/21)
Report
Questions
- Summarise the effects of different levels of global warming as predicted by the IPCC report.
- To what extent is global warming an example of the ‘tragedy of the commons’?
- How could prices be affected by government policy so as to provide an incentive to reduce carbon emissions?
- What incentives could be put in place to encourage people to cut their own individual carbon footprint?
- To what extent is game theory relevant to understanding the difficulties of achieving international action on reducing carbon emissions?
- Identify four different measures that a government could adopt to reduce carbon emissions and assess the likely effectiveness of these measures.